The binding of RecA protein to duplex DNA molecules is directional and is promoted by a single stranded region.

RecA protein from E. coli binds more strongly to single stranded DNA than to duplex molecules. Using duplex DNA that contains single stranded gaps, we have studied the protection by RecA protein at various concentrations, of restriction sites as a function of their distance from the single stranded region. We show that the binding of RecA protein, initiated in the single stranded region, extends progressively along the adjoining duplex in the 5' to 3' direction with respect to the single stranded region. The strand exchange reaction is known to proceed in the same direction.     

Role of SSB protein in RecA promoted branch migration reactions

Summary The RecA protein ofEscherichia coli is essential for genetic recombination and postreplicational repair of DNA. In vitro, RecA protein promotes strand transfer reactions between full length linear duplex and single stranded circular DNA of X174 to form heteroduplex replicative form II-like structures (Cox and Lehman 1981a). In a similar way, it transfers one strand of a short duplex restriction fragment to a single stranded circle. Both reactions require RecA and single strand binding protein (SSB) in amounts sufficient to saturate the ssDNA. The rate and extent of strand transfer is enhanced considerably when SSB is added after preincubation of the DNA with RecA protein. In contrast, SSB protein is not required for RecA protein catalysed reciprocal strand exchanges between regions of duplex DNA. These results indicate that while SSB is necessary for efficient transfer between linear duplex and ssDNA to form a single heteroduplex, it is not required for branch migration reactions between duplex molecules that form two heteroduplexes.Abbreviations SSB single strand binding protein - ssDNA single stranded DNA - X phage X174 - bp base pairs - ATP[S] adenosine 5-O-(gamma-thiotriphosphate)     

Salt dependent changes in structure and dynamics of circular single stranded DNA of filamentous phages of Escherichia coli

We have analyzed the static and dynamic behaviour of the circular single stranded DNA of the filamentous Escherichia coli phages F1 and M13mp8 in solution as a function of salt concentration using static and dynamic light scattering and sedimentation analysis in the analytical ultracentrifuge. We show by static light scattering that native and denatured single stranded DNA behave like a randomly coiled macromolecule at all salt concentrations used. The size of the native single stranded DNA is governed by the formation of secondary structures. While the radius of gyration decreases with increasing salt concentration the translational diffusion of the center-of-mass of native single stranded DNA and the sedimentation coefficient increase with increasing salt concentration in a biphasic manner. Below 100 mM monovalent cation concentration there is a strong dependence of the hydrodynamic parameters upon salt which is reduced approx. 3-fold at higher salt concentrations. We attribute the compaction of single stranded DNA by salt to electrostatic shielding and, in case of native single stranded DNA, secondary structure formation. Internal motions of the native single stranded DNA are observable at all salt concentrations and can be interpreted with a model of segmental diffusion of the elements of the polymer chain. The observed segmental diffusion coefficient of the native single stranded polynucleotide increases with increasing salt under the conditions investigated.     

RecA stimulates AlkB-mediated direct repair of DNA adducts

The Escherichia coli AlkB protein is a 2-oxoglutarate/Fe(II)-dependent demethylase that repairs alkylated single stranded and double stranded DNA. Immunoaffinity chromatography coupled with mass spectrometry identified RecA, a key factor in homologous recombination, as an AlkB-associated protein. The interaction between AlkB and RecA was validated by yeast two-hybrid assay; size-exclusion chromatography and standard pull down experiment and was shown to be direct and mediated by the N-terminal domain of RecA. RecA binding results AlkB–RecA heterodimer formation and RecA–AlkB repairs alkylated DNA with higher efficiency than AlkB alone.     

Head to head dimer model; an alternative model for the strand exchange reaction by RecA protein of Escherichia coli

The RecA protein of E coli promotes a strand exchange reaction in vitro which appears to be similar to homologous genetic recombination in vivo. A model for the mechanism of strand transfer reaction by RecA protein has been proposed by Howard-Flanders et al based on the assumption that the RecA monomer has two distinctive DNA binding sites both of which can bind to ssDNA as well as dsDNA. Here, I propose an alternative model based on the assumption that RecA monomer has a single domain for binding to a polynucleotide chain with a unique polarity. In addition, the model is based on a few mechanical assumptions that, in the presence of ATP, two RecA molecules form a head to head dimer as the basic binding unit to DNA, and that the binding of RecA protein to a polynucleotide chain induces a structural change of RecA protein that causes a higher state of affinity for another RecA molecule that is expressed as cooperativy. The model explains many of the biochemical capabilities of RecA protein including the polar polymerization of RecA protein on single stranded DNA and polar strand transfer of DNA by the protein as well as the formation of a joint DNA molecule in a paranemic configuration. The model also presents the energetics in the strand transfer reaction.     

Design and evaluation of a tryptophanless RecA protein with wild type activity

The C-terminal domain of the Escherichia coli RecA protein contains two tryptophan residues whose native fluorescence emission provides an interfering background signal when other fluorophores such as 1,N(6)-ethenoadenine, 2-aminopurine and other tryptophan residues are used to probe the protein's activities. Replacement of the wild type tryptophans with nonfluorescent residues is not trivial because one tryptophan is highly conserved and the C-terminal domain functions in both DNA binding as well as interfilament protein-protein contact. We undertook the task of creating a tryptophanless RecA protein with WT RecA activity by selecting suitable amino acid replacements for Trp290 and Trp308. Mutant proteins were screened in vivo using assays of SOS induction and cell survival following UV irradiation. Based on its activity in these assays, the W290H-W308F W-less RecA was purified for in vitro characterization and functioned like WT RecA in DNA-dependent ATPase and DNA strand exchange assays. Spectrofluorometry indicates that the W290H-W308F RecA protein generates no significant emission when excited with 295-nm light. Based on its ability to function as wild type protein in vivo and in vitro, this dark RecA protein will be useful for future fluorescence experiments.     

Regulation of RecA protein binding to DNA by opposing effects of ATP and ADP on inter-domain contacts: analysis by urea-induced unfolding of wild-type and C-terminal truncated RecA

RecA protein requires ATP and its hydrolysis to ADP to complete the DNA strand-exchange reaction. We investigated how the nucleotides activate RecA by examining their effect on urea-induced unfolding, which could reflect domain-domain contact of protein. RecA is folded into three continuous domains: the N-terminal, central and C-terminal domains. The fluorescence of tyrosine residues, which lie mainly in the central domain, was modified in 1-3 M urea, while the red shift of fluorescence peak of the tryptophan residues located in the C-terminal domain occurred only in 3-6 M urea. Thus, the C-terminal domain of RecA is unfolded after the central part unfolds. The change in intensity of tryptophan fluorescence without a large shift in the peak at low concentrations of urea suggests that there are weak interactions between the central and C-terminal domains. This is supported by our observation that RecA protein lacking the C-terminal tail unfolded at lower concentrations of urea than the entire RecA, and with clear transitions, unlike the entire RecA. ATP and its unhydrolyzable analog (ATPgammaS), which enhance the binding of RecA to DNA, facilitated the urea-induced change in RecA tryptophan fluorescence, while ADP, an antagonist of ATP, prevented the change. ATP probably weakens the domain-domain contact and facilitates the DNA binding, while ADP stabilizes the contact and inhibits it. Supporting this conclusion, the binding of RecA lacking the C-terminal tail to DNA was not inhibited by ADP, while that of the intact RecA was.     

Regulation in repressor inactivation by RecA protein

Treatments that damage DNA or inhibit DNA synthesis in E. coli induce the expression of a set of functions called SOS functions that are involved in DNA repair, mutagenesis, arrest of cell division and prophage induction. Induction of SOS functions is triggered by inactivation of the LexA repressor or a phage repressor. Inactivation of these repressors results from their cleavage by the E. coli RecA protein in the presence of single-stranded DNA and a nucleoside triphosphate.We found that these cleavage reactions are controlled by two mechanisms in vitro: one is through the structural change of the RecA protein in the ternary complex, RecA-ssDNA-ATP-γ-S. The active ternary complex is formed by binding of ATP-γ-S to a complex of RecA protein and ssDNA. On the other hand, when the RecA protein binds to ATP-γ-S prior to its binding to ssDNA, the resulting complex has no or only very weak cleavage activity toward the repressor. This structural change is negatively controlled by its C-terminal part. The loss of the 25 amino acid residues from the C-terminal leads the RecA protein to stable binding to dsDNA as well as ssDNA, and the protein takes the activated form for the repressor cleavage constitutively. The other mechanism is through the structural change of the repressor. The cleavage reaction of a ∅80cI repressor is greatly stimulated by the presence of d(G-G), and d(G-G) stimulates the cleavage by binding to the C-terminal half of the ∅80cI repressor. Moreover, the C-terminal fragment of the cleaved products of the 80cI repressor was able to cleave a ∅80cI-λ chimeric repressor. These results strongly suggested that th active site of the repressor cleavage was located in the C-terminal domain of the repressor and that the C-terminal fragment produced by the cleavage could cleave the repressor.     

A temperature sensitive Reca protein of Escherichia coli

Summary The temperature sensitive allele recA200 has been cloned into the multiple copy number plasmid pBR322 and the gene product isolated. The purified RecA200 protein is temperature sensitive in ability to cleave the phage and LexA repressors in vitro and also in ability to promote a successful search for homology between single stranded DNA and a homologous duplex leading to D-loop formation. However, at the non-permissive temperature the RecA200 protein has approximately wild type single stranded DNA dependent ATPase activity and ability to promote pairing between homologous single DNA strands. The demonstration that the temperature sensitivity in vivo can be correlated with the temperature sensitive cleavage of the and LexA repressors in vitro and also with D-loop formation shows that these in vitro reactions, which require large amounts of RecA protein, are not carried out by trace amounts of contaminating proteins.     

C-terminal deletions of the Escherichia coli RecA protein. Characterization of in vivo and in vitro effects

A set of C-terminal deletion mutants of the RecA protein of Escherichia coli, progressively removing 6, 13, 17, and 25 amino acid residues, has been generated, expressed, and purified. In vivo, the deletion of 13 to 17 C-terminal residues results in increased sensitivity to mitomycin C. In vitro, the deletions enhance binding to duplex DNA as previously observed. We demonstrate that much of this enhancement involves the deletion of residues between positions 339 and 346. In addition, the C-terminal deletions cause a substantial upward shift in the pH-reaction profile of DNA strand exchange reactions. The C-terminal deletions of more than 13 amino acid residues result in strong inhibition of DNA strand exchange below pH 7, where the wild-type protein promotes a proficient reaction. However, at the same time, the deletion of 13-17 C-terminal residues eliminates the reduction in DNA strand exchange seen with the wild-type protein at pH values between 7.5 and 9. The results suggest the existence of extensive interactions, possibly involving multiple salt bridges, between the C terminus and other parts of the protein. These interactions affect the pK(a) of key groups involved in DNA strand exchange as well as the direct binding of RecA protein to duplex DNA.     

C-terminal truncated Escherichia coli RecA protein RecA5327 has enhanced binding affinities to single- and double-stranded DNAs.

RecA5327 is a truncated RecA protein that is lacking 25 amino acid residues from the C-terminal end. The expression of RecA5327 protein in the cell resulted in the constitutive induction of SOS functions without damage to the DNA. Purified RecA5327 protein effectively promoted the LexA repressor cleavage reaction and ATP hydrolysis at a lower concentration of single-stranded DNA than that required for wild-type RecA protein. A DNA binding study showed that RecA5327 has about ten times higher affinity for single-stranded DNA than does the wild-type RecA protein. Moreover RecA5327 protein binds stably to double-stranded (ds) DNA in conditions where the wild-type RecA protein could not bind. The binding of RecA5327 protein to dsDNA was associated with the unwinding of dsDNA, suggesting that RecA5327 binds to dsDNA in the same manner as does the wild-type protein. The fact that RecA5327 does not bind stoichiometrically but forms short filaments on dsDNA suggests that it nucleates to dsDNA much more frequently than does the wild-type protein. The role of the 25 C-terminal residues, in the regulation of RecA binding to DNA, is discussed.     

Structure and dynamics of the complex of single stranded DNA binding protein of Escherichia coli with circular single stranded DNA of filamentous phages

We have analyzed the equilibrium and nonequilibrium properties of the complex of the single stranded DNA binding protein of Escherichia coli (EcoSSB) and circular single stranded DNA of filamentous phages M13mp8 and F1 using static and dynamic light scattering, analytical ultracentrifugation and electron microscopy. Upon binding to the single stranded DNA the EcoSSB tetramer replaces an equivalent volume of water trapped within the coiled single stranded DNA and hinders the folding of the single stranded DNA into secondary structures at all salt concentrations. The salt dependent compaction of the stoichiometric complex can be described assuming a flexible polyelectrolyte chain. The solution structure of the macromolecular complex is a random coil and in the electron microscope a beaded flexible structure of the complex with a bead diameter of 6 nm appears at all salt concentrations used. The internal motions of the stoichiometric complex can be described by the Rouse-Zimm model of polymer dynamics. The segmental mobility of the complex can be correlated with changes in the binding site size of the EcoSSB tetramer; it indicates the presence of interactions between EcoSSB tetramers bound to single stranded DNA.     

Cloning and expression in Escherichia coli of a recA-like gene from Bacteroides fragilis

The recombinant plasmid pHG100, containing a 5.2-kb DNA fragment from Bacteroides fragilis, complemented defects in homologous recombination, DNA repair and prophage induction to various levels in an Escherichia coli recA mutant strain. There was no DNA homology between the cloned B. fragilis recA-like gene and E. coli chromosomal DNA. pHG100 produced two proteins with Mr of approx. 39,000 and 37,000 which cross-reacted with antibodies raised against E. coli RecA protein. The production of these proteins was not increased after UV induction. The cloned B. fragilis recA-like gene product did not enhance the production of native but defective E. coli RecA protein after UV irradiation.     

The C terminus of the Escherichia coli RecA protein modulates the DNA binding competition with single-stranded DNA-binding protein

The nucleation step of Escherichia coli RecA filament formation on single-stranded DNA (ssDNA) is strongly inhibited by prebound E. coli ssDNA-binding protein (SSB). The capacity of RecA protein to displace SSB is dramatically enhanced in RecA proteins with C-terminal deletions. The displacement of SSB by RecA protein is progressively improved when 6, 13, and 17 C-terminal amino acids are removed from the RecA protein relative to the full-length protein. The C-terminal deletion mutants also more readily displace yeast replication protein A than does the full-length protein. Thus, the RecA protein has an inherent and robust capacity to displace SSB from ssDNA. However, the displacement function is suppressed by the RecA C terminus, providing another example of a RecA activity with C-terminal modulation. RecADeltaC17 also has an enhanced capacity relative to wild-type RecA protein to bind ssDNA containing secondary structure. Added Mg(2+) enhances the ability of wild-type RecA and the RecA C-terminal deletion mutants to compete with SSB and replication protein A. The overall binding of RecADeltaC17 mutant protein to linear ssDNA is increased further by the mutation E38K, previously shown to enhance SSB displacement from ssDNA. The double mutant RecADeltaC17/E38K displaces SSB somewhat better than either individual mutant protein under some conditions and exhibits a higher steady-state level of binding to linear ssDNA under all conditions.     

Mouse DNA methylase: methylation of native DNA.

An improved method of purification of DNA methylase from Krebs II ascites cells is reported. The enzyme sediments at 8.3 S on glycerol-gradients and a major band on SDS polyacrylamide gel electrophoresis has a molecular weight of 184 000. Aggregation occurs at low salt and this may interfere with enzymic activity. The preferred double stranded DNA substrate is that rendered partially unmethylated by an in vitro repair mechanism or by isolation from methionine starved cells. Methylation of native partially methylated DNA is favoured under conditions of low salt and high temperature; conditions which encourage 'breathing' of the DNA. Methylation of native, unmethylated DNA also involves breathing but results in formation of a salt resistant tight binding complex between the enzyme and the DNA.     

A recombinational defect in the C-terminal domain of Escherichia coli RecA2278-5 protein is compensated by protein binding to ATP

RecA2278-5 is a mutant RecA protein (RecAmut) bearing two amino acid substitutions, Gly-278 to Thr and Val-275 to Phe, in the α-helix H of the C-terminal sub-domain of the protein. recA2278-5 mutant cells are unusual in that they are thermosensitive for recombination but almost normal for DNA repair of UV damage and the SOS response. Biochemical analysis of purified RecAmut protein revealed that its temperature sensitivity is suppressed by prior binding of this protein to its ligand. In fact, the preheating of RecAmut protein for several minutes at a restrictive temperature (42°C) in the absence of ATP resulted in inhibition at 42°C of many activities related to homologous recombination including ss- and dsDNA binding, high-affinity binding for ATP, ss- or dsDNA-dependent ATPase, RecA–RecA interaction, and strand transfer capability. The binary complex RecAmut::ATP under the same conditions showed a decrease in only two activities, i.e. dsDNA binding and high-affinity binding for ATP. Besides ATP, sodium acetate (1.5M) was shown to be another factor that can stabilize the RecAmut protein at 42°C, judging by restoration of its DNA-free ATPase activity. The similarity of influence of high salt (with its non-specific binding) and ATP (binding specifically) on the apparent protein folding stability suggests that the structural stability of the RecA C-terminal domain is one of the conditions for correct interaction between RecA protein and ATP in the RecA::ATP::ssDNA presynaptic complex formation. The decrease in affinity for ATP was suggested to be the factor that determined a particular recombinational (but not repair) thermosensitivity of the RecAmut protein. Finally, we show that the stability of C-terminal domain appeared to be necessary for the dsDNA-binding activity of the protein.     

General mechanism for RecA protein binding to duplex DNA

RecA protein binding to duplex DNA occurs by a multi-step process. The tau analysis, originally developed to examine the binding of RNA polymerase to promoter DNA, is adapted here to study two kinetically distinguishable reaction segments of RecA-double stranded (ds) DNA complex formation in greater detail. One, which is probably a rapid preequilibrium in which RecA protein binds weakly to native dsDNA, is found to have the following properties: (1) a sensitivity to pH, involving a net release of approximately one proton; (2) a sensitivity to salts; (3) little or no dependence on temperature; (4) little or no dependence on DNA length. The second reaction segment, the rate-limiting nucleation of nucleoprotein filament formation accompanied by partial DNA unwinding, is found to have the following properties: (1) a sensitivity to pH, involving a net uptake of approximately three protons; (2) a sensitivity to salts; (3) a relatively large dependence on temperature, with an Arrhenius activation energy of 39 kcal mol(-1); (4) a sensitivity to DNA topology; (5) a dependence on DNA length. These results contribute to a general mechanism for RecA protein binding to duplex DNA, which can provide a rationale for the apparent preferential binding to altered DNA structures such as pyrimidine dimers and Z-DNA.     

Complexes of RecA with LexA and RecX differentiate between active and inactive RecA nucleoprotein filaments

The bacterial RecA protein has been the dominant model system for understanding homologous genetic recombination. Although a crystal structure of RecA was solved ten years ago, we still do not have a detailed understanding of how the helical filament formed by RecA on DNA catalyzes the recognition of homology and the exchange of strands between two DNA molecules. Recent structural and spectroscopic studies have suggested that subunits in the helical filament formed in the RecA crystal are rotated when compared to the active RecA-ATP-DNA filament. We examine RecA-DNA-ATP filaments complexed with LexA and RecX to shed more light on the active RecA filament. The LexA repressor and RecX, an inhibitor of RecA, both bind within the deep helical groove of the RecA filament. Residues on RecA that interact with LexA cannot be explained by the crystal filament, but can be properly positioned in an existing model for the active filament. We show that the strand exchange activity of RecA, which can be inhibited when RecX is present at very low stoichiometry, is due to RecX forming a block across the deep helical groove of the RecA filament, where strand exchange occurs. It has previously been shown that changes in the nucleotide bound to RecA are associated with large motions of RecA's C-terminal domain. Since RecX binds from the C-terminal domain of one subunit to the nucleotide-binding core of another subunit, a stabilization of RecA's C-terminal domain by RecX can likely explain the inhibition of RecA's ATPase activity by RecX.     

Polyamine-dependent deoxyribonuclease activity from rat-liver nuclei.

When nuclei isolated from rat liver in a low salt buffer were washed with 0.1 M NaCl solution, the supernatant showed a deoxyribonuclease (DNase) activity. The activity required Mg2+ and in addition spermine or spermidine, and its optimal pH was 7.2-7.4. The activity was higher on denatured (single stranded) DNA than on double-helical DNA. With both substrates the activity was highest at a polyamine concentration at which the DNA-polyamine complex began to precipitate. No Mg2++Ca2+ dependent DNase activity was detected in the preparation.     

Postreplication repair in E. coli: strand exchange reactions of gapped DNA by RecA protein

Summary We have used a sensitive gel electrophoresis assay to detect the products of Escherichia coli RecA protein catalysed strand exchange reactions between gapped and duplex DNA molecules. We identify structures that correspond to joint molecules formed by homologous pairing, and show that joint molecules are converted by RecA protein into heteroduplex monomers by reciprocal strand exchanges. However, strand exchanges only occur when there is a 3-terminus complementary to the single stranded DNA in the gap. In the absence of a complementary free end, the two DNA molecules pair and short heteroduplex regions are formed by localised interwinding.