recA protein promoted DNA strand exchange

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

Complete inhibition of Streptococcus pneumoniae RecA protein-catalyzed ATP hydrolysis by single-stranded DNA-binding protein (SSB protein): implications for the mechanism of SSB protein-stimulated DNA strand exchange

The ATP-dependent three-strand exchange activity of the Streptococcus pneumoniae RecA protein (RecA(Sp)), like that of the Escherichia coli RecA protein (RecA(Ec)), is strongly stimulated by the single-stranded DNA-binding protein (SSB) from either E. coli (SSB(Ec)) or S. pneumoniae (SSB(Sp)). The RecA(Sp) protein differs from the RecA(Ec) protein, however, in that its ssDNA-dependent ATP hydrolysis activity is completely inhibited by SSB(Ec) or SSB(Sp) protein, apparently because these proteins displace RecA(Sp) protein from ssDNA. These results indicate that in contrast to the mechanism that has been established for the RecA(Ec) protein, SSB protein does not stimulate the RecA(Sp) protein-promoted strand exchange reaction by facilitating the formation of a presynaptic complex between the RecA(Sp) protein and the ssDNA substrate. In addition to acting presynaptically, however, it has been proposed that SSB(Ec) protein also stimulates the RecA(Ec) protein strand exchange reaction postsynaptically, by binding to the displaced single strand that is generated when the ssDNA substrate invades the homologous linear dsDNA. In the RecA(Sp) protein-promoted reaction, the stimulatory effect of SSB protein may be due entirely to this postsynaptic mechanism. The competing displacement of RecA(Sp) protein from the ssDNA substrate by SSB protein, however, appears to limit the efficiency of the strand exchange reaction (especially at high SSB protein concentrations or when SSB protein is added to the ssDNA before RecA(Sp) protein) relative to that observed under the same conditions with the RecA(Ec) protein.     

A postsynaptic role for single-stranded DNA-binding protein in recA protein-promoted DNA strand exchange.

The single-stranded DNA-binding protein (SSB protein) is required for efficient genetic recombination in vivo. One function for SSB protein in DNA strand exchange in vitro is to remove secondary structure from single-stranded DNA (ssDNA) and thereby aid in the formation of recA protein-saturated presynaptic complexes. In the preceding paper (Lavery, P. E., and Kowalczykowski, S. C. (1992) J. Biol. Chem. 267, 9307-9314) we demonstrated that DNA strand exchange can occur in the presence of volume-occupying agents at low magnesium ion concentration, where secondary structures are reduced. Our results suggest that SSB protein is not acting during presynapsis under these conditions, yet the DNA strand exchange reaction is stimulated by the addition of SSB protein. In this study we present biochemical evidence which suggests that SSB protein stimulates DNA strand exchange by binding to the ssDNA displaced from joint molecules, thereby stabilizing them and allowing branch migration to extend the region of heteroduplex DNA. Therefore, our results indicate dual roles for SSB protein at elevated magnesium ion concentration; it functions during presynapsis, removing secondary structure from ssDNA, as indicated previously, and it also functions postsynaptically, binding to the ssDNA displaced from joint molecules.     

Enhancement of recA protein-promoted DNA strand exchange activity by volume-occupying agents.

To investigate the in vivo effects of macromolecular crowding we examined the effect of inert macromolecules such as polyvinyl alcohol and polyethylene glycol on the in vitro activity of recA protein. The addition of either of these volume-occupying agents enables recA protein to promote homologous pairing and exchange of DNA strands at an otherwise nonpermissive magnesium ion concentration. In the presence of these macromolecules, both the rate of recA protein association with single-stranded DNA (ssDNA) and the steady-state affinity of recA protein for ssDNA are increased. Consequently, the ability of recA protein to compete with ssDNA-binding protein (SSB protein) is enhanced, and the inhibitory effects of SSB protein on the formation of recA protein-ssDNA presynaptic complexes are eliminated. Because the ability of recA protein to bind to ssDNA-containing secondary structures is also enhanced in volume-occupied solution, joint molecule formation is not greatly reduced when SSB protein is omitted from the reaction. Thus, increased recA protein interactions with ssDNA contribute to enhanced presynaptic complex formation. In addition, polyvinyl alcohol and polyethylene glycol must also affect another property of recA protein, i.e. self-association, which is required for synapsis and DNA strand exchange. Our examination of DNA strand exchange in the presence of volume-occupying agents helps to reconcile the requirement for elevated magnesium ion concentrations in recA protein-promoted recombination reactions in vitro, with a presumably low magnesium ion concentration in vivo.     

Patterns of nuclease protection during strand exchange. recA protein forms heteroduplex DNA by binding to strands of the same polarity

recA protein, in the presence of ATP, polymerizes on single-stranded DNA (plus strand) to form a presynaptic nucleoprotein filament that pairs with linear duplex DNA and actively displaces the plus strand from the recipient molecule in a polarized fashion to form a new heteroduplex molecule. The interaction between recA protein and DNA during strand exchange was studied by labeling different strands and probing the intermediate with pancreatic deoxyribonuclease I (DNase I) or restriction endonuclease. The incoming single strand was resistant to DNase I in the original nucleoprotein filament and remained resistant even after extensive strand exchange had occurred. Both strands of the parental duplex molecule were sensitive to DNase I in the absence of joint molecule formation; but as strand exchange progressed following homologous pairing, increasing stretches of the parental plus strand became resistant, whereas the complementary parental minus strand remained sensitive to DNase I throughout the reaction. Except for a region of 50-100 base pairs at the end of the newly formed heteroduplex DNA where strand exchange was initiated, the rest of the heteroduplex region was resistant to cleavage by restriction endonucleases. The data suggest that recA protein promotes strand exchange by binding both the incoming and outgoing strands of the same polarity, whereas the complementary strand, which must switch pairing partners, is unhindered by direct contact with the protein.     

Duplex-duplex interactions catalyzed by recA protein allow strand exchanges to pass double-strand breaks in DNA

Using gapped circular DNA and homologous duplex DNA cut with restriction nucleases, we show that E. coli RecA protein promotes strand exchanges past double-strand breaks. The products of strand exchange are heteroduplex DNA molecules that contain nicks, which can be sealed by DNA ligase, thereby effecting the repair of double-strand breaks in vitro. These results show that RecA protein can promote pairing interactions between homologous DNA molecules at regions where both are duplex. Moreover, pairing leads to strand exchanges and the formation of heteroduplex DNA. In contrast, strand exchanges are unable to pass a double-strand break in the gapped substrate. This apparent paradox is discussed in terms of a model for RecA-DNA interactions in which we propose that each RecA monomer contains two nonequivalent DNA-binding sites.     

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.     

Homology-dependent changes in adenosine 5'-triphosphate hydrolysis during recA protein promoted DNA strand exchange: evidence for long paranemic complexes

As a first step in DNA strand exchange, recA protein forms a filamentous complex on single-stranded DNA (ssDNA), which contains stoichiometric (one recA monomer per four nucleotides) amounts of recA protein. recA protein monomers within this complex hydrolyze ATP with a turnover number of 25 min-1. Upon introduction of linear homologous duplex DNA to initiate strand exchange, this rate of ATP hydrolysis drops by 33%. The decrease in rate is complete in less than 2 min, and the rate of ATP hydrolysis then remains constant during and subsequent to the strand exchange reaction. This drop is completely dependent upon homology in the duplex DNA. In addition, the magnitude of the drop is linearly dependent upon the length of the homologous region in the linear duplex DNA. Linear DNA substrates in which pairing is topologically restricted to a paranemic joint also follow this relationship. Taken together, these properties imply that all of the available homology in the incoming duplex DNA is detected very early in the DNA strand exchange reaction, with the linear duplex DNA paired paranemically with the homologous ssDNA in the complex throughout its length. The results indicate that paranemic joints can extend over thousands of base pairs. We note elsewhere [Pugh, B. F., & Cox, M. M. (1987b) J. Biol. Chem. 262, 1337-1343] that this duplex acquires resistance to digestion by DNase with a much slower time course (30 min), which parallels the progress of strand exchange. Together these results imply that the duplex DNA is paired with the ssDNA but remains outside the nucleoprotein filament. Finally, the results also support the notion that ATP hydrolysis occurs throughout the recA nucleoprotein filament.     

Biochemical basis of the constitutive repressor cleavage activity of recA730 protein. A comparison to recA441 and recA803 proteins.

The recA730 mutation results in constitutive SOS and prophage induction. We examined biochemical properties of recA730 protein in an effort to explain the constitutive activity observed in recA730 strains. We find that recA730 protein is more proficient than the wild-type recA protein in the competition with single-stranded DNA binding protein (SSB protein) for single-stranded DNA (ssDNA) binding sites. Because an increased aptitude in the competition with SSB protein has been previously reported for recA441 protein and recA803 protein, we directly compared their in vitro activities with those of recA730 protein. At low magnesium ion concentration, both ATP hydrolysis and lexA protein cleavage experiments demonstrate that these recA proteins displace SSB protein from ssDNA in a manner consistent with their in vivo repressor cleavage activity, i.e. recA730 protein > recA441 protein > recA803 protein > recAwt protein. Additionally, a correlation exists between the proficiency of the recA proteins in SSB protein displacement and their rate of association with ssDNA. We propose that an increased rate of association with ssDNA allows recA730 protein to displace SSB protein from the ssDNA that occurs naturally in Escherichia coli and thereby to become activated for the repressor cleavage that leads to SOS induction. RecA441 protein is similarly activated for repressor cleavage; however, in this case, significant SSB protein displacement occurs only at elevated temperature. At physiological magnesium ion concentration, we argue that recA803 protein and wild-type recA protein do not displace sufficient SSB protein from ssDNA to constitutively induce the SOS response.     

Properties of RecA441 protein reveal a possible role for RecF and SSB proteins in Escherichia coli

Summary We examined the possibility that the recA441 mutation, which partially suppresses the UV sensitivity of uvr recF mutant bacteria, exerts its effect by coding for an altered RecA protein that competes more efficiently than the RecA⁺ protein with SSB for ssDNA in vivo. Using an assay measuring recombination between UV-damaged DNA and intact homologous DNA, we found that the introduction of the recA441 mutation partially suppressed the defects in recombination in bacteria lacking RecF activity but not in bacteria with excess SSB, although recombination was affected more in recF mutants than in bacteria overproducing SSB. These results therefore do not support the hypothesis that RecA441 protein, or RecA protein with the help of RecF protein, is required during recombination of UV-damaged DNA to compete with SSB for ssDNA.     

RecA protein promotes strand exchange with DNA substrates containing isoguanine and 5-methyl isocytosine

The Escherichia coli RecA protein pairs homologous DNA molecules and promotes DNA strand exchange in vitro. We have examined DNA strand exchange between a 70 nucleotide ssDNA fragment and a 40 bp duplex, in which all G and C residues (at 18 positions distributed throughout the 40 bp exchanged region) were replaced with the nonstandard nucleosides 2'-deoxyisoguanosine (iG) and 2'-deoxy-5-methylisocytidine (MiC), respectively. We demonstrate that the nonstandard oligonucleotides are substrates for the RecA protein, permitting DNA strand exchange in vitro at a rate and efficiency comparable to exchange with normal DNA substrates. This observation provides an expanded experimental basis for discussions of potential roles for iG and MiC in a genetic code. Experiments of this type also provide another avenue for exploring RecA-facilitated DNA pairing mechanisms.     

Purification and properties of the recA protein of Proteus mirabilis. Comparison with Escherichia coli recA protein; specificity of interaction with single strand binding protein

The product of the cloned recA+ gene of Proteus mirabilis substitutes for a defective recA protein in Escherichia coli recA- mutants and restores recombination, repair, and prophage induction functions to near normal levels (Eitner, G., Adler, B., Lanzov, V. A., and Hofemeister, J. (1982) Mol. Gen. Genet. 185, 481-486). In this paper, we report the purification to near homogeneity of the P. mirabilis recA protein (recApm). The polypeptide has a molecular weight similar to that of E. coli recA protein (recAec) and shows partial identity with recAec when reacted against antibodies specific for the E. coli recA protein. recApm catalyzes the hydrolysis of ATP in the presence of single-stranded but not double-stranded DNA. We have compared the recombination-like activities of recApm with those of recAec and found them to be similar. In the presence of ATP and Mg2+, stoichiometric amounts of recApm promote the complete reciprocal exchange of strands between gapped circular and linear duplex DNA molecules. The enzyme also efficiently promotes the formation of D-loops from circular duplex DNA and homologous single-stranded fragments. However, although recApm and recAec share the above physical and functional similarities, they differ in their ability to interact with the E. coli single strand binding protein to catalyze the transfer of one DNA strand from a linear duplex to a single-stranded circle.     

The accessibility of DNA to dimethylsulfate in complexes with recA protein.

recA protein coats DNA co-operatively to form filaments approximately 100 A thick, which in the presence of ATP, and more stably so in the presence of the non-hydrolyzable analog ATP gamma S, have a helical appearance with a deep cleft in the protein coat. This protein helix follows the DNA helix, to which it imparts a new helicity of 18.5 bp per turn of 97 A pitch. Here we test the accessibility of the DNA in the complex to modification by dimethylsulfate, and find that the complexed DNA is approximately 2-fold more reactive on the major groove side than it was in B-DNA (methylation of guanine N7), while it is protected approximately 2-fold on the minor groove side (methylation of adenine N3), suggesting that the protein coats the DNA along the minor groove. Furthermore, N3 of cytosine, a residue involved in base pairing, is found exposed in complexes with single strands as it is in naked single-stranded DNA, while it remains inaccessible in complexes with double strands, suggesting that the latter is not melted at this stage of the strand exchange reaction.     

The Mycobacterium tuberculosis recA intein can be used in an ORFTRAP to select for open reading frames

The DNA repair protein RecA of Mycobacterium tuberculosis contains an intein, a self-splicing protein element. We have employed this Mtu recA intein to create a selection system for successful intein splicing by inserting it into a kanamycin-resistance gene so that functional antibiotic resistance can only be restored upon protein splicing. We then proceeded to develop an ORFTRAP, i.e., a selection system for the cloning of open reading frames (ORFs). The ORFTRAP exploits the self-splicing properties of inteins (which depend on full-length in-frame translation of a precursor protein) by allowing protein splicing to occur when DNA fragments encoding ORFs are inserted into the Mtu recA intein, whereas DNA fragments containing non-ORFs are selected against. Regions of the Mtu recA intein that tolerate the insertion of additional amino acids were identified by Bgl II linker scanning mutagenesis, and a respective construct was chosen as the ORFTRAP. To test the maximum insert size that could be cloned into ORFTRAP, DNA fragments of increasing length from the Listeria monocytogenes hly gene as well as a genomic library of Haemophilus influenzae were inserted and it was found that the longest permissive inserts were 425 bp and 251 bp, respectively. The H. influenzae ORFTRAP library also demonstrated the strength (strong selection power) and weakness (insertion of very small fragments) of the system. Further modifications should make the ORFTRAP useful for protein expression, epitope mapping, and antigen screening.     

DNA binding proteins from calf thymus with an enhanced ability to stimulate DNA polymerase α in vitro

We have isolated from calf thymus glands a new class of single-stranded DNA binding proteins (DBP) specifically endowed with the ability to stimulate DNA polymerase α activity $\text{in vitro}$. Such result was attained by using a partially new purification procedure and a functional assay, i.e. stimulation of DNA polymerase α on poly(dAT) throughout purification. We observed stimulations up to 30-fold of DNA polymerase α on poly(dAT) at a protein: DNA ratio of 1:1, that is much below the saturating level. Such stimulation is specific for DNA polymerase α. These results indicate a possible direct functional interaction between our DBP, polymerase α and the template.     

Single-stranded DNA binding protein and DNA helicase of bacteriophage T7 mediate homologous DNA strand exchange.

Two proteins encoded by bacteriophage T7, the gene 2.5 single-stranded DNA binding protein and the gene 4 helicase, mediate homologous DNA strand exchange. Gene 2.5 protein stimulates homologous base pairing of two DNA molecules containing complementary single-stranded regions. The formation of a joint molecule consisting of circular, single-stranded M13 DNA, annealed to homologous linear, duplex DNA having 3'- or 5'-single-stranded termini of approximately 100 nucleotides requires stoichiometric amounts of gene 2.5 protein. In the presence of gene 4 helicase, strand transfer proceeds at a rate of > 120 nucleotides/s in a polar 5' to 3' direction with respect to the invading strand, resulting in the production of circular duplex M13 DNA. Strand transfer is coupled to the hydrolysis of a nucleoside 5'-triphosphate. The reaction is dependent on specific interactions between gene 2.5 protein and gene 4 protein.     

The direction of RecA protein assembly onto single strand DNA is the same as the direction of strand assimilation during strand exchange

The RecA protein of Escherichia coli optimally promotes DNA strand exchange reactions in the presence of the single strand DNA-binding protein of E. coli (SSB protein). Under these conditions, assembly of RecA protein onto single-stranded DNA (ssDNA) occurs in three steps. First, the ssDNA is rapidly covered by SSB protein. The binding of RecA protein is then initiated by nucleation of a short tract of RecA protein onto the ssDNA. Finally, cooperative polymerization of additional RecA protein accompanied by displacement of SSB protein results in a ssDNA-RecA protein filament (Griffith, J. D., Harris, L. D., and Register, J. C. (1984) Cold Spring Harbor Symp. Quant. Biol. 49, 553-559). We report here that RecA protein assembly onto circular ssDNA yields RecA protein-covered circles in which greater than 85% are completely covered by RecA protein with no remaining SSB protein-covered segments (as detected by electron microscopy). However, when linear ssDNA is used, 90% of the filaments contain a short segment at one end complexed with SSB protein. This suggests that RecA protein assembly is unidirectional. Visualization of the assembly of RecA protein onto either long ssDNA tails (containing either 5' or 3' termini) or ssDNA gaps generated in double strand DNA allowed us to determine that the RecA protein polymerizes in the 5' to 3' direction on ssDNA and preferentially nucleates at ssDNA-double strand DNA junctions containing 5' termini.     

Properties of the high-affinity single-stranded DNA binding state of the Escherichia coli recA protein

The properties of the high-affinity single-stranded DNA (ssDNA) binding state of Escherichia coli recA protein have been studied. We find that all of the nucleoside triphosphates that are hydrolyzed by recA protein induce a high-affinity ssDNA binding state. The effect of ATP binding to recA protein was partially separated from the ATP hydrolytic event by substituting calcium chloride for magnesium chloride in the binding buffer. Under these conditions, the rate of ATP hydrolysis is greatly inhibited. ATP increases the affinity of recA protein for ssDNA in a concentration-dependent manner in the presence of both calcium and magnesium chloride with apparent Kd values of 375 and 500 microM ATP, respectively. Under nonhydrolytic conditions, the molar ratio of ATP to ADP has an effect on the recA protein ssDNA binding affinity. Over an ATP/ADP molar ratio of 2-3, the affinity of recA protein for ssDNA shifts cooperatively from a low-to a high-affinity state.