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.     

Purification and characterization of an activity from Saccharomyces cerevisiae that catalyzes homologous pairing and strand exchange.

An activity that catalyzes the formation of joint molecules from linear M13mp19 replicative form DNA and circular M13mp19 viral DNA was purified 1000- to 2000-fold from mitotic Saccharomyces cerevisiae cells. The activity appeared to reside in a Mr 132,000 polypeptide. The reaction required that the substrates be homologous and also required Mg2+. There was no requirement for ATP. The reaction required stoichiometric amounts of protein and showed a cooperative dependence on protein concentration. Electron microscopic analysis of the joint molecules indicated they were formed by displacement of one strand of the linear duplex by the single-stranded circular molecule. This analysis also showed that heteroduplex formation started at the 3'-homologous end of the linear duplex strand followed by extension of the hybrid region toward the 5'-homologous end of the linear duplex strand (3'-to-5' direction).     

3'' homologous free ends are required for stable joint molecule formation by the RecA and single-stranded binding proteins of Escherichia coli.

The RecA protein of Escherichia coli is important for genetic recombination in vivo and can promote synapsis and strand exchange in vitro. The DNA pairing and strand exchange reactions have been well characterized in reactions with circular single strands and linear duplexes, but little is known about these two processes using substrates more characteristic of those likely to exist in the cell. Single-stranded linear DNAs were prepared by separating strands of duplex molecules or by cleaving single-stranded circles at a unique restriction site created by annealing a short defined oligonucleotide to the circle. Analysis by gel electrophoresis and electron microscopy revealed that, in the presence of RecA and single-stranded binding proteins, a free 3' homologous end is essential for stable joint molecule formation between linear single-stranded and circular duplex DNA.     

Polarity of heteroduplex formation promoted by Escherichia coli recA protein.

When recA protein pairs circular single strands with linear duplex DNA, the circular strand displaces its homolog from only one end of the duplex molecule and rapidly creates heteroduplex joints that are thousands of base pairs long [DasGupta, C., Shibata, T., Cunningham, R. P. & Radding, C. M. (1980) Cell 22, 437-446]. To examine this apparently polar reaction, we prepared chimeric duplex fragments of DNA that had M13 nucleotide sequences at one end and G4 sequences at the other. Circular single strands homologous to M13 DNA paired with a chimeric fragment when M13 sequences were located at the 3' end of the complementary strand but did not pair when the M13 sequences were located at the 5' end. Likewise circular single-stranded G4 DNA paired with chimeric fragments only when G4 sequences were located at the 3' end of the complementary strand. To confirm these observations, we prepared fd DNA labeled only at the 5' or 3' end of the plus strand, and we examined the susceptibility of these labeled ends to digestion by exonucleases when joint molecules were formed. Eighty percent of the 5' label in joint molecules became sensitive to exonuclease VII. Displacement of that 5' end by recA protein was concerted because it did not occur in the absence of single-stranded DNA or in the presence of heterologous single strands. By contrast, only a small fraction of the 3' label became sensitive to exonuclease VII or exonuclease I. These observations show that recA protein forms heteroduplex joints in a concerted and polarized way.     

Visualization of the paranemic joining of homologous DNA molecules catalyzed by the RecA protein of Escherichia coli.

In reactions catalyzed by the RecA protein of Escherichia coli, synapsis between two DNA molecules is believed to occur even in the absence of free homologous DNA ends and to involve a metastable interaction termed paranemic joining. We have used electron microscopic methods to visualize synapse formation between supertwisted M13 double-stranded DNA (dsDNA) and linear M13 mp7 single-stranded DNA (ssDNA) with non-M13 sequences at its ends. These non-M13 sequences block strand invasion and make this pairing equivalent to the joining of two fully circular molecules. We observed a high frequency of joining when the ssDNA was initially assembled into presynaptic filaments with RecA protein. Cleavage of the dsDNA in the joined complexes by Hpa I revealed that the joint was at a site of homology. In these joints, the dsDNA entered the presynaptic filament over a length of 360 +/- 80 base pairs, not visibly altering its ultrastructure, and then dissociated from the filament. Although the dsDNA in the complexes appeared topologically relaxed, deproteinization released supertwisted dsDNA, indicating that the dsDNA was unwound by 34 degrees per base pair in the paranemic joint. When supertwisted M13 dsDNA was paired with circular M13 ssDNA, similar joints were observed and both DNA circles appeared topologically relaxed.     

Identification of homologous pairing and strand-exchange activity from a human tumor cell line based on Z-DNA affinity chromatography.

An enzymatic activity that catalyzes ATP-dependent homologous pairing and strand exchange of duplex linear DNA and single-stranded circular DNA has been purified several thousand-fold from a human leukemic T-lymphoblast cell line. The activity was identified after chromatography of nuclear proteins on a Z-DNA column matrix. The reaction was shown to transfer the complementary single strand from a donor duplex linear substrate to a viral circular single-stranded acceptor beginning at the 5' end and proceeding in the 3' direction (5'----3'). Products of the strand-transfer reaction were characterized by electron microscopy. A 74-kDa protein was identified as the major ATP-binding peptide in active strand transferase fractions. The protein preparation described in this report binds more strongly to Z-DNA than to B-DNA.     

Heteroduplex formation by recA protein: polarity of strand exchanges.

Purified recA protein promotes strand exchanges between linear duplex DNA and homologous circular single-stranded phage phi X174 DNA that carries a short hybridized fragment [West, S. C., Cassuto, E. & Howard-Flanders, P. (1981) Proc. Natl. Acad. Sci. USA 78, 2100-2104]. In this paper we investigate the mechanism of this strand exchange reaction. We show that recA protein initiates strand exchanges by pairing the free end of the duplex fragment with the single-stranded DNA. In addition, we find that strand exchanges are polar, stable heteroduplex molecules being formed by the directional transfer transfer of the (-) strands starting at 3' termini.     

Polar branch migration promoted by recA protein: effect of mismatched base pairs.

Escherichia coli recA protein makes joint molecules from single-stranded circular phage DNA (viral or plus strand) and homologous linear duplex DNA by a polar reaction that displaces the 5' end of the plus strand from the duplex molecule [Kahn, R., Cunningham, R. P., DasGupta, C. & Radding, C. M. (1981) Proc. Natl. Acad. Sci. USA 78, 4786-4790]. Growth of the heteroduplex joint, which results from strand exchange or branch migration, stopped at the borders of regions of nonhomologous DNA that were variously located 145, 630, or 1202 nucleotides from the end. Accumulation of migrating branches at heterologous borders demonstrates that their migration is not the result of random diffusion but is actively driven by recA protein. Growth of the heteroduplex joint was blocked even when a heterologous insertion was located in the single-stranded DNA, a case in which the flexible single-stranded region might conceivably fold out of the way under some condition. The recA protein did not make joint molecules from phage phi X174 and G4DNAs, which are 70% homologous, but did join phage fd and M13DNAs, which are 97% homologous. In the latter case, heteroduplex joints extended through regions containing isolated mismatched base pairs but stopped in a region where the fd and M13 sequences differ by an average of 1 base pair in 10. These results suggest that in genetic recombination the discrimination of perfect or near-perfect homology from a high degree of relatedness may be attributable in part to the mechanism by which recA protein promotes strand transfer.     

Drosophila Rrp1 protein: an apurinic endonuclease with homologous recombination activities.

A protein previously purified from Drosophila embryo extracts by a DNA strand transfer assay, Rrp1 (recombination repair protein 1), has an N-terminal 427-amino acid region unrelated to known proteins, and a 252-amino acid C-terminal region with sequence homology to two DNA repair nucleases, Escherichia coli exonuclease III and Streptococcus pneumoniae exonuclease A, which are known to be active as apurinic endonucleases and as double-stranded DNA 3' exonucleases. We demonstrate here that purified Rrp1 has apurinic endonuclease and double-stranded DNA 3' exonuclease, activities and carries out single-stranded DNA renaturation in a Mg(2+)-dependent manner. Strand transfer, 3' exonuclease, and single-stranded DNA renaturation activities comigrate during column chromatography. The properties of Rrp1 suggest that it could promote homologous recombination at sites of DNA damage.     

Rad54 protein stimulates the postsynaptic phase of Rad51 protein-mediated DNA strand exchange

Rad54 and Rad51 are important proteins for the repair of double-stranded DNA breaks by homologous recombination in eukaryotes. As previously shown, Rad51 protein forms nucleoprotein filaments on single-stranded DNA, and Rad54 protein directly interacts with such filaments to enhance synapsis, the homologous pairing with a double-stranded DNA partner. Here we demonstrate that Saccharomyces cerevisiae Rad54 protein has an additional role in the postsynaptic phase of DNA strand exchange by stimulating heteroduplex DNA extension of established joint molecules in Rad51/Rpa-mediated DNA strand exchange. This function depended on the ATPase activity of Rad54 protein and on specific protein:protein interactions between the yeast Rad54 and Rad51 proteins.     

Evidence for the double-strand break repair model of bacteriophage lambda recombination.

We have obtained evidence for the repair of double-strand gaps promoted by the Red function of bacteriophage lambda. A double-strand gap was made in one of the two regions of homology in an inverted orientation on a plasmid DNA molecule. The gapped plasmid was introduced into Escherichia coli cells expressing the red alpha (exo) and red beta (bet) genes of lambda. The gap was repaired by DNA synthesis copying an intact duplex. This gap repair was sometimes accompanied by reciprocal recombination (crossing over). The gap stimulated recombination about 100-fold. Our results are compatible with previous proposals that lambda homologous recombination involves the following early steps: (i) generation of double-stranded ends by the packaging machinery or by the replication machinery; (ii) production of a single-stranded tail with a 3'-hydroxyl end by 5'----3' degradation by lambda exonuclease (red alpha gene product); (iii) pairing of the single-stranded tail with a complementary strand from a homologous duplex with the help of beta protein (red beta gene product); (iv) priming of DNA synthesis at this 3'-hydroxyl end to copy the second DNA molecule.     

Directionality and polarity in recA protein-promoted branch migration.

The recA protein of Escherichia coli promotes the complete exchange of strands between full-length linear duplex and single-stranded circular phi X174 DNA molecules. Analysis of the reaction by electron microscopy confirms that D loops containing short heteroduplex regions are rapidly formed at the ends of the linear duplex, followed by a relatively slow branch migration that converts the D loops to nicked circular duplexes (RFII) and displaced linear single strands. Heteroduplex extension and displacement of the linear single strand are concerted. Heterologous sequences within the linear duplex halt branch migration and lead to the accumulation of D loops. Although D loops can be formed at either end of the linear duplex, recA protein-promoted branch migration proceeds uniquely in the 3' leads to 5' direction relative to the (--) strand of the linear duplex.     

Branch migration during Rad51-promoted strand exchange proceeds in either direction

The Saccharomyces cerevisiae Rad51 protein is important for genetic recombination and repair of DNA double-strand breaks in vivo and can promote strand exchange between linear double-stranded DNA and circular single-stranded DNA in vitro. However, unlike Escherichia coli RecA, Rad51 requires an overhanging complementary 3′ or 5′ end to initiate strand exchange; given that fact, we previously surmised that the fully exchanged molecules resulted from branch migration in either direction depending on which type of end initiated the joint molecule. Our present experiments confirm that branch migration proceeds in either direction, the polarity depending on whether a 3′ or 5′ end initiates the joint molecules. Furthermore, heteroduplex DNA is formed rapidly, first at the overhanging end of the linear double-stranded DNA’s complementary strand and then more slowly by progressive lengthening of the heteroduplex region until strand exchange is complete. Although joint molecule formation occurs equally efficiently when initiated with a 3′ or 5′ overhanging end, branch migration proceeds more rapidly when it is initiated by an overhanging 3′ end, i.e., in the 5′ to 3′ direction with respect to the single-stranded DNA.     

Helical repeat of DNA in the region of homologous pairing

The process of DNA strand exchange during general genetic recombination is initiated within protein-stabilized synaptic filaments containing homologous regions of interacting DNA molecules. The RecA protein in bacteria and its analogs in eukaryotic organisms start this process by forming helical filamentous complexes on single-stranded or partially single-stranded DNA molecules. These complexes then progressively bind homologous double-stranded DNA molecules so that homologous regions of single- and double-stranded DNA molecules become aligned in register while presumably winding around common axis. The topological assay presented herein allows us to conclude that in synaptic complexes containing homologous single- and double-stranded DNA molecules, all three DNA strands have a helicity of approximately 19 nt per turn.     

Strand specificity of DNA unwinding by RecBCD enzyme.

RecBCD enzyme (exonuclease V) of Escherichia coli unwinds DNA, frequently forming asymmetric structures with two single-stranded tails of unequal length abutting a single-stranded loop at the junction with double-stranded DNA. Their lengths are consistent with the longer tail being one strand of the duplex and the loop plus the shorter tail being the other strand. The strand polarity of the unwinding was determined by labeling the 3' or 5' ends of duplex DNA with biotinylated nucleotides, reacting the DNA with RecBCD enzyme, and distinguishing the labeled ends, in the electron microscope, by their binding to streptavidin-gold complex. The shorter tail was formed from the DNA strand with its 3' terminus at the duplex end where RecBCD enzyme entered. We conclude that RecBCD enzyme unwinds DNA by forming a loop on the strand with a 3' end at the entry point. This result is concordant with a previously proposed model of recombination, which we discuss.     

A recombinase from Drosophila melanogaster embryos.

We have partially purified a DNA strand-exchange activity (recombinase) from nuclear extracts of Drosophila melanogaster embryos. The protein fraction forms a joint molecule between a circular single-strand DNA and a homologous linear duplex DNA that is resolved from the substrates by agarose gel electrophoresis. A strand-exchange activity can be obtained from nuclear extracts from embryos as old as 24 hr. The activity is similar to that partially purified from human cells [Hsieh, P., Meyn, S.M. & Camerini-Otero, R.D. (1986) Cell 44, 885-894]. It is homology-dependent, requires Mg2+, appears to be directional in that it prefers to displace the 3' end of the noncomplementary strand, and does not require exogenous ATP. Forty nanograms of protein in the partially purified DNA strand-exchange fraction from D. melanogaster embryos can completely convert 50 ng of substrate single-strand DNA into joint molecules in 10 min. In the electron microscope, joint molecules are seen to consist of a circular single-strand DNA molecule attached to only one end of a linear duplex DNA molecule; a displaced strand is also seen. The region of heteroduplex formation can be as long as 600 base pairs. The demonstration of a strand-exchange activity from wild-type D. melanogaster embryos invites analysis of recombination-defective mutants to explore the role of DNA strand exchange in homologous recombination.     

Strand invasion promoted by recombination protein beta of coliphage lambda

Studies of phage lambda in vivo have indicated that its own recombination enzymes, beta protein and lambda exonuclease, are capable of catalyzing two dissimilar pathways of homologous recombination that are widely distributed in nature: single-strand annealing and strand invasion. The former is an enzymatic splicing of overlapping ends of broken homologous DNA molecules, whereas the latter is characterized by the formation of a three-stranded synaptic intermediate and subsequent strand exchange. Previous studies in vitro have shown that beta protein has annealing activity, and that lambda exonuclease, acting on branched substrates, can produce a perfect splice that requires only ligation for completion. The present study shows that beta protein can initiate strand invasion in vitro, as evidenced both by the formation of displacement loops (D-loops) in superhelical DNA and by strand exchange between colinear single-stranded and double-stranded molecules. Thus, beta protein can catalyze steps that are central to both strand annealing and strand invasion pathways of recombination. These observations add beta protein to a set of diverse proteins that appear to promote recognition of homology by a unitary mechanism governed by the intrinsic dynamic properties of base pairs in DNA.     

recA protein promotes homologous-pairing and strand-exchange reactions between duplex DNA molecules.

Purified recA protein, product of the recA+ gene, promotes homologous pairing between intact covalent circular duplex DNA and circular single-stranded DNA carrying a short hybridized fragment [West, S. C., Cassuto, E. & Howard-Flanders, P. (1981) Nature (London) 290, 29-33.]. In this paper we investigate the interaction of duplex fragments with circular single-stranded DNA carrying the hybridized fragment and find that recA protein promotes an efficient strand-exchange reaction between interacting DNA molecules. The exchange is dependent upon linear duplex DNA fragments that are homologous to, but extend beyond, the short fragment present on the hybridized DNA substrate. The reactions require stoichiometric amounts of recA protein and the presence of ATP.     

Isolation of Exonuclease VIII: The Enzyme Associated with the sbcA Indirect Suppressor

recB and/or recC deficiency in Escherichia coli K-12 is indirectly suppressed by the presence of sbcA(-) mutations. sbcA(-) strains contain an increased level of an ATP-independent nuclease. Genetic and enzymatic tests indicate that this activity is not exonuclease III, exonuclease V (recB-recC nuclease), DNA polymerase I, or lambda exonuclease. This new enzyme (exonuclease VIII) has been purified 750-fold and shows a striking preference for double-stranded DNA over heat-denatured DNA. It does not act endonucleolytically on closed circular, single-stranded DNA as exonuclease V does. It also lacks a 3'-phosphatase function. Analysis on sodium dodecyl sulfate-polyacrylamide gels indicates that exonuclease VIII is not present in unsuppressed (sbcA(+)) strains. It is thought that sbcA determines some type of control function; the structural gene for exonuclease VIII is denoted by recE.     

Homologous pairing in genetic recombination: complexes of recA protein and DNA.

recA protein, which is essential for general genetic recombination in Escherichia coli, promotes the homologous pairing of single-stranded DNA with double-stranded DNA to form a D loop. The amount of recA protein required for the reaction was directly proportional to the amount of single stranded DNA and was unaffected by similar variations in the amount of double-stranded DNA. The ATP analog, adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S), which was not rapidly hydrolyzed by recA protein, blocked the formation of D loops but promoted the formation of stable complexes of recA protein and single-stranded DNA. These complexes, in turn, bound homologous or heterologous double-stranded DNA and partially unwound it. Because ATP gamma S competitively inhibited the ATPase activity of recA protein (Km/Ki approximately 300), we infer that ATP gamma S binds at a site that overlaps the site for ATP and that the functional complexes formed in the presence of the analog probably represent partial steps in the overall reaction. If the complexes formed in the presence of ATP gamma S reflect natural intermediates in the formation of D loops, recA protein must promote homologous pairing either by moving juxtaposed single-stranded and double-stranded DNA relative to one another or by forming and dissociating complexes reiteratively until a homologous match occurs.