The DNA binding properties of Saccharomyces cerevisiae Rad51 protein

Saccharomyces cerevisiae Rad51 protein is the paradigm for eukaryotic ATP-dependent DNA strand exchange proteins. To explain some of the unique characteristics of DNA strand exchange promoted by Rad51 protein, when compared with its prokaryotic homologue the Escherichia coli RecA protein, we analyzed the DNA binding properties of the Rad51 protein. Rad51 protein binds both single-stranded DNA (ssDNA) and double-stranded DNA (dsDNA) in an ATP- and Mg2+-dependent manner, over a wide range of pH, with an apparent binding stoichiometry of approximately 1 protein monomer per 4 (+/-1) nucleotides or base pairs, respectively. Only dATP and adenosine 5'-gamma-(thiotriphosphate) (ATPgammaS) can substitute for ATP, but binding in the presence of ATPgammaS requires more than a 5-fold stoichiometric excess of protein. Without nucleotide cofactor, Rad51 protein binds both ssDNA and dsDNA but only at pH values lower than 6.8; in this case, the apparent binding stoichiometry covers the range of 1 protein monomer per 6-9 nucleotides or base pairs. Therefore, Rad51 protein displays two distinct modes of DNA binding. These binding modes are not inter-convertible; however, their initial selection is governed by ATP binding. On the basis of these DNA binding properties, we conclude that the main reason for the low efficiency of the DNA strand exchange promoted by Rad51 protein in vitro is its enhanced dsDNA-binding ability, which inhibits both the presynaptic and synaptic phases of the DNA strand exchange reaction as follows: during presynapsis, Rad51 protein interacts with and stabilizes secondary structures in ssDNA thereby inhibiting formation of a contiguous nucleoprotein filament; during synapsis, Rad51 protein inactivates the homologous dsDNA partner by directly binding to it.     

Targeted recombination with single-stranded DNA vectors in mammalian cells

We studied the ability of single-stranded DNA (ssDNA) to participate in targeted recombination in mammalian cells. A 5' end-deleted adenine phosphoribosyltransferase (aprt) gene was subcloned into M13 vector, and the resulting ssDNA and its double-stranded DNA (dsDNA) were transfected to APRT-Chinese hamster ovary cells with a deleted aprt gene. APRT+ recombinants with the ssDNA was obtained at a frequency of 3 x 10(-7) per survivor, which was almost equal to that with the double-stranded equivalent. Analysis of the genome in recombinant clones produced by ssDNA revealed that 12 of 14 clones resulted from correction of the deletion in the aprt locus. On the other hand, the locus of the remaining 2 was not corrected; instead, the 5' deletion of the vector was corrected by end extension, followed by integration into random sites of the genome. To exclude the possibility that input ssDNA was converted into its duplex form before participating in a recombination reaction, we compared the frequency of extrachromosomal recombination between noncomplementary ssDNAs, and between one ssDNA and one dsDNA, of two phage vectors. The frequency with the ssDNAs was 0.4 x 10(-5), being 10-fold lower than that observed with the ssDNA and the dsDNA, suggesting that as little as 10% of the transfected ssDNA was converted into duplex forms before the recombination event, hence 90% remained unchanged as single-stranded molecules. Nevertheless, the above finding that ssDNA was as efficient as dsDNA in targeted recombination suggests that ssDNA itself is able to participate directly in targeted recombination reactions in mammalian cells.     

Purification and characterization of XRad51.1 protein, Xenopus RAD51 homologue: recombinant XRad51.1 promotes strand exchange reaction

BACKGROUND: The RAD51 gene of Saccharomyces cerevisiae is homologous to the Escherichia coli recA gene and plays a key role in genetic recombination and DNA double-strand break repair. To construct an improved experimental system of homologous recombination in higher eukaryotes, we have chosen the South African clawed frog, Xenopus laevis, whose egg extracts might be useful for the in vitro studies. We identified and characterized a Xenopus homologue of RAD51 gene, the XRAD51.1. RESULTS: Recombinant XRad51.1 was expressed in E. coli. The purified XRad51.1 protein showed ssDNA-dependent ATPase activity and promoted the DNA strand exchange reaction between two 55-mer oligonucleotides. The binding stoichiometry of XRad51.1 to ssDNA was determined by fluorescence of poly(d epsilonA), a chemically modified poly(dA), and was found to be about six bases/XRad51.1 monomer in a nucleoprotein filament, a similar value to E. coli RecA protein. The kinetics of the fluorescence change of poly(d epsilonA) after XRad51.1 binding in the presence of ATP was significantly different from that observed with RecA protein. The affinity of XRad51.1 to ssDNA in the presence of ATP was higher than that of RecA protein, and the dissociation of the XRad51.1-ssDNA complex was slower than the RecA-ssDNA complex. CONCLUSIONS: Purified recombinant XRad51.1 protein promoted the strand exchange between short DNA molecules. While the binding stoichiometry of XRad51.1 protein to ssDNA was identical to that of the RecA protein, XRad51.1 has a significantly higher affinity and binding stability to ssDNA than did the RecA protein in the presence of ATP.     

The human Rad51 protein: polarity of strand transfer and stimulation by hRP-A

The human Rad51 protein is homologous to the RecA protein and catalyses homologous pairing and strand transfer reactions in vitro. Using single-stranded circular and homologous linear duplex DNA, we show that hRad51 forms stable joint molecules by transfer of the 5' end of the complementary strand of the linear duplex to the ssDNA. The polarity of strand transfer is therefore 3' to 5', defined relative to the ssDNA on which hRad51 initiates filament formation. This polarity is opposite to that observed with RecA. Homologous pairing and strand transfer require stoichiometric amounts of hRad51, corresponding to one hRad51 monomer per three nucleotides of ssDNA. Joint molecules are not observed when the protein is present in limiting or excessive amounts. The human ssDNA binding-protein, hRP-A, stimulates hRad51-mediated reactions. Its effect is consistent with a role in the removal of secondary structures from ssDNA, thereby facilitating the formation of continuous Rad51 filaments.     

The uvsY recombination protein of bacteriophage T4 forms hexamers in the presence and absence of single-stranded DNA

A prerequisite to genetic recombination in the T4 bacteriophage is the formation of the presynaptic filament-a helical nucleoprotein filament containing stoichiometric amounts of the uvsX recombinase in complex with single-stranded DNA (ssDNA). Once formed, the filament is competent to catalyze homologous pairing and DNA strand exchange reactions. An important component in the formation of the presynaptic filament is the uvsY protein, which is required for optimal uvsX-ssDNA assembly in vitro, and essential for phage recombination in vivo. uvsY enhances uvsX activities by promoting filament formation and stabilizing filaments under conditions of low uvsX, high salt, and/or high gp32 (ssDNA-binding protein) concentrations. The molecular properties of uvsY include noncooperative binding to ssDNA and specific protein-protein interactions with both uvsX and gp32. Evidence suggests that all of these hetero-associations of the uvsY protein are important for presynaptic filament formation. However, there is currently no structural information available on the uvsY protein itself. In this study, we present the first characterization of the self-association of uvsY. Using hydrodynamic methods, we demonstrate that uvsY associates into a stable hexamer (s020,w = 6.0, M = 95 kDa) in solution and that this structure is competent to bind ssDNA. We further demonstrate that uvsY hexamers are capable of reversible association into higher aggregates in a manner dependent on both salt and protein concentration. The implications for presynaptic filament formation are discussed.     

High resolution computed tomography (HRCT) of pulmonary infections in AIDS patients

The Escherichia coli RuvA and RuvB proteins mediate ATP-dependent branch migration of Holliday junctions during homologous genetic recombination. RuvA is a DNA-binding protein with high affinity for Holliday junctions, to which it directs RuvB (a DNA-dependent ATPase). Electron microscopic studies have shown that RuvB forms double hexameric rings on duplex DNA. To determine whether the rings are biologically active, the conditions required for their formation and activity have been analysed. The quaternary structure of RuvB appears to be dependent upon the binding of ATP, magnesium ions, and the presence of RuvA. In the presence of Mg2+ and ATP, RuvB forms hexamers; however, in the presence of Mg2+ alone, dodecamers were observed. Both forms of the protein are stable and have been isolated by gel filtration. Performed dodecamers and, to a lesser extent, hexamers assembled in the absence of DNA lack ATPase activity. Maximal ATPase activity was observed when RuvB assembled directly on DNA in the presence of Mg2+ and ATP. Moreover, under these conditions, a direct interaction between RuvB hexamers and tetramers of RuvA was observed.     

Probing of DNA-binding sites of Escherichia coli RecA protein utilizing 1-anilinonaphthalene-8-sulfonic acid

RecA protein of Escherichia coli plays an essential role in homologous recombination of DNA strands. To analyze the interaction of RecA with single-stranded DNA (ssDNA), we performed a fluorescence competition assay employing 1-anilinonaphthalene-8-sulfonic acid (ANS) as an extrinsic fluorescent probe. ANS bound to RecA at three sites, leading to enhancement of ANS fluorescence. Addition of synthetic polynucleotides to the RecA-ANS complex in the absence of a nucleotide quenched the ANS fluorescence, indicating displacement of ANS molecules by ssDNA. Less effective quenching by poly(dA) suggests that the nucleoprotein filament on poly(dA) may differ from those on poly(dT) and poly(dC). A titration experiment with poly(dT) and poly(dA) showed clear stoichiometric binding of 3.5 nucleotides per protein. The site size for poly(dC) was 7.0, which could be explained by the formation of a double helix of poly(dC). ATP and other nucleotides also displaced the ANS. To identify ANS-binding sites, ANS was incorporated into RecA by UV irradiation, and fluorescent peptides were isolated from the proteolytic digest. Sequence analysis suggested that ANS binds to or near the ATP-binding region. These results suggest that the fluorescence quenching and photoincorporation assay using ANS may be useful for the analysis of the interaction of a protein and its ligand.     

Protein interactions in genetic recombination in Escherichia coli. Interactions involving RecO and RecR overcome the inhibition of RecA by single-stranded DNA-binding protein

RecA promotes homologous pairing of single-stranded DNA (ssDNA) with double-stranded DNA (dsDNA). This reaction occurs inefficiently if the ssDNA substrate is preincubated with Escherichia coli ssDNA-binding protein (SSB). However, RecO and RecR can act together as accessory factors for RecA to overcome this inhibition by SSB (Umezu, K., Chi, N.-W., and Kolodner, R. D. (1993) Proc. Natl. Acad. Sci. U.S.A. 90, 3875-3879). To elucidate the mechanism that underlies this process, we examined protein-protein interactions between RecA, RecF, RecO, RecR, and SSB, and characterized the structure and activity of the ssDNA complexes formed with different combinations of these proteins. We obtained the following results. (i) RecO physically interacts with both RecR and SSB. The interaction between RecO and SSB is stronger than the RecO-RecR interaction. (ii) RecO and RecR do not remove SSB from SSB.ssDNA complexes, but instead bind to these complexes. The resulting RecO.RecR.SSB.ssDNA complexes were more active in RecA-mediated joint molecule formation than were SSB.ssDNA complexes. (iii) RecA can nucleate on the RecO.RecR.SSB.ssDNA complexes more efficiently than on SSB.ssDNA complexes. (iv) When RecA presynaptic filaments were formed in the presence of SSB, RecO, and RecR, the protein-DNA complexes obtained contained 70% of the amount of RecA required to saturate ssDNA. These complexes, however, can mediate joint molecule formation and strand exchange as efficiently as presynaptic filaments which are fully saturated with RecA. Based on these results, we propose dual roles for RecO and RecR in joint molecule formation. First, RecO and RecR bind to SSB.ssDNA complexes and modify their structure to allow RecA to nucleate on them efficiently. Second, RecO and RecR are retained in RecA presynaptic filaments and play a role in the subsequent homologous pairing process promoted by RecA.     

Three mechanistic steps detected by FRET after presynaptic filament formation in homologous recombination. ATP hydrolysis required for release of oligonucleotide heteroduplex product from RecA

The Escherichia coli RecA protein promotes DNA strand exchange in homologous recombination and recombinational DNA repair. Stopped-flow kinetics and fluorescence resonance energy transfer (FRET) were used to study RecA-mediated strand exchange between a 30-bp duplex DNA and a homologous single-stranded 50mer. In our standard assay, one end of the dsDNA helix was labeled at apposing 5' and 3' ends with hexachlorofluorescein and fluorescein, respectively. Strand exchange was monitored by the increase in fluorescence emission resulting upon displacement of the fluorescein-labeled strand from the initial duplex. The potential advantages of FRET in study of strand exchange are that it noninvasively measures real-time kinetics in the previously inaccessible millisecond time regime and offers great sensitivity. The oligonucleotide substrates model short-range mechanistic effects that might occur within a localized region of the ternary complex formed between RecA and long DNA molecules during strand exchange. Reactions in the presence of ATP with 0.1 microM duplex and 0.1-1.0 microM ss50mer showed triphasic kinetics in 600 s time courses, implying the existence of three mechanistic steps subsequent to presynaptic filament formation. The observed rate constants for the intermediate phase were independent of the concentration of ss50mer and most likely characterize a unimolecular isomerization of the ternary complex. The observed rate constants for the first and third phases decreased with increasing ss50mer concentration. Kinetic experiments performed with the nonhydrolyzable analogue ATPgammaS showed overall changes in fluorescence emission identical to those observed in the presence of ATP. In addition, the observed rate constants for the two fastest reaction phases were identical in ATP or ATPgammaS. The observed rate constant for the slowest phase showed a 4-fold reduction in the presence of ATPgammaS. Results in ATPgammaS using an alternate fluorophore labeling pattern suggest a third ternary intermediate may form prior to ssDNA product release. The existence of two or three ternary intermediates in strand exchange with a 30 bp duplex suggests the possibility that the step size for base pair switching may be 10-15 bp. Products of reactions in the presence of ATP and ATPgammaS, with and without proteinase K treatment, were analyzed on native polyacrylamide gels. In reactions in which only short-range RecA-DNA interactions were important, ATP hydrolysis was not required for recycling of RecA from both oligonucleotide products. Hydrolysis or deproteinization was required for RecA to release the heteroduplex product, but not the outgoing single strand.     

Kinetic analysis of pairing and strand exchange catalyzed by RecA. Detection by fluorescence energy transfer

RecA is a 38-kDa protein from Escherichia coli that polymerizes on single-stranded DNA, forming a nucleoprotein filament that pairs with homologous duplex DNA and carries out strand exchange in vitro. In this study, we measured RecA-catalyzed pairing and strand exchange in solution by energy transfer between fluorescent dyes on the ends of deoxyribo-oligonucleotides. By varying the position of the dyes in separate assays, we were able to detect the pairing of single-stranded RecA filament with duplex DNA as an increase in energy transfer, and strand displacement as a decrease in energy transfer. With these assays, the kinetics of pairing and strand displacement were studied by stopped-flow spectrofluorometry. The data revealed a rapid, second order, reversible pairing step that was followed by a slower, reversible, first order strand exchange step. These data indicate that an initial unstable intermediate exists which can readily return to reactants, and that a further, rate-limiting step (or steps) is required to effect or complete strand exchange.     

No sliding during homology search by RecA protein

The RecA protein of Escherichia coli is a prototype of the RecA/Rad51 family of proteins that exist in virtually all the organisms. In a process called DNA synapsis, RecA first polymerizes onto a single-stranded DNA (ssDNA) molecule; the resulting RecA-ssDNA complex then searches for and binds to a double-stranded DNA (dsDNA) molecule containing the almost identical, or "homologous, " sequence. The RecA-ssDNA complex thus can be envisioned as a sequence-specific binding entity. How does the complex search for its target buried within nonspecific sequences? One possible mechanism is the sliding mechanism, in which the complex first binds to a dsDNA molecule nonspecifically and then linearly diffuses, or slides, along the dsDNA. To understand the mechanism of homology search by RecA, this sliding model was tested. A plasmid containing four homologous targets in tandem was constructed and used as the dsDNA substrate in the synapsis reaction. If the sliding is the predominant search mode, the two outermost targets should act as more efficient targets than the inner targets. No such positional preference was observed, indicating that a long range sliding of the RecA-ssDNA complex does not occur. These and other available data can be adequately explained by a simple three-dimensional random collision mechanism.     

A phage single-stranded DNA (ssDNA) binding protein complements ssDNA accumulation of a geminivirus and interferes with viral movement

Geminiviruses are plant viruses with circular single-stranded DNA (ssDNA) genomes encapsidated in double icosahedral particles. Tomato leaf curl geminivirus (ToLCV) requires coat protein (CP) for the accumulation of ssDNA in protoplasts and in plants but not for systemic infection and symptom development in plants. In the absence of CP, infected protoplasts accumulate reduced levels of ssDNA and increased amounts of double-stranded DNA (dsDNA), compared to accumulation in the presence of wild-type virus. To determine whether the gene 5 protein (g5p), a ssDNA binding protein from Escherichia coli phage M13, could restore the accumulation of ssDNA, ToLCV that lacked the CP gene was modified to express g5p or g5p fused to the N-terminal 66 amino acids of CP (CP66:6G:g5). The modified viruses led to the accumulation of wild-type levels of ssDNA and high levels of dsDNA. The accumulation of ssDNA was apparently due to stable binding of g5p to viral ssDNA. The high levels of dsDNA accumulation during infections with the modified viruses suggested a direct role for CP in viral DNA replication. ToLCV that produced the CP66:6G:g5 protein did not spread efficiently in Nicotiana benthamiana plants, and inoculated plants developed only very mild symptoms. In infected protoplasts, the CP66:6G:g5 protein was immunolocalized to nuclei. We propose that the fusion protein interferes with the function of the BV1 movement protein and thereby prevents spread of the infection.     

The herpes simplex virus type 1 helicase-primase. Analysis of helicase activity

The rate of unwinding of duplex DNA by the herpes simplex virus type 1 (HSV-1)-encoded helicase-primase (primosome) was determined by measuring the rate of appearance of single strands from a circular duplex DNA containing a 40-nucleotide 5' single-stranded tail, i.e. a preformed replication fork, in the presence of the HSV-1 single strand DNA-binding protein, infected cell protein 8 (ICP8). With this substrate, the rate at low ionic strength was highly sensitive to Mg2+ concentration. The Mg2+ dependence was a reflection of both the requirement for ICP8 for helicase activity and the ability of ICP8 to reverse the helicase reaction as a consequence of its capacity to anneal homologous single strands at Mg2+ concentrations in excess of 3 mM. The rate of unwinding of duplex DNA by the HSV-1 primosome was also determined indirectly by measuring the rate of leading strand synthesis with a preformed replication fork as template in the presence of the T7 DNA polymerase. The value of 60-65 base pairs unwound/s by both methods is consistent with the rate of 50 base pairs/s estimated for the rate of fork movement in vivo during replication of pseudorabies virus, another herpesvirus. Interaction with the helicase-primase did not increase its helicase activity.     

Visualisation of human rad52 protein and its complexes with hRad51 and DNA

The human Rad52 protein stimulates joint molecule formation by hRad51, a homologue of Escherichia coli RecA protein. Electron microscopic analysis of hRad52 shows that it self-associates to form ring structures with a diameter of approximately 10 nm. Each ring contains a hole at its centre. hRad52 binds to single and double-stranded DNA. In the ssDNA-hRad52 complexes, hRad52 was distributed along the length of the DNA, which exhibited a characteristic "beads on a string" appearance. At higher concentrations of hRad52, "super-rings" (approximately 30 nm) were observed and the ssDNA was collapsed upon itself. In contrast, in dsDNA-hRad52 complexes, some regions of the DNA remained protein-free while others, containing hRad52, interacted to form large protein-DNA networks. Saturating concentrations of hRad51 displaced hRad52 from ssDNA, whereas dsDNA-Rad52 complexes (networks) were more resistant to hRad51 invasion and nucleoprotein filament formation. When Rad52-Rad51-DNA complexes were probed with gold-conjugated hRad52 antibodies, the presence of globular hRad52 structures within the Rad51 nucleoprotein filament was observed. These data provide the first direct visualisation of protein-DNA complexes formed by the human Rad51 and Rad52 recombination/repair proteins.     

Characterization of a mutant RecA protein that facilitates homologous genetic recombination but not recombinational DNA repair: RecA423

A recA mutant (recA423; Arg169-->His), with properties that should help clarify the relationship between the biochemical properties of RecA protein and its two major functions, homologous genetic recombination and recombinational DNA repair, has been isolated. The mutant has been characterized in vivo and the purified RecA423 protein has been studied in vitro. The recA423 cells are nearly as proficient in conjugational recombination, transductional recombination, and recombination of lambda red- gam- phage as wild-type cells. At the same time, the mutant cells are deficient for intra-chromosomal recombination and nearly as sensitive to UV irradiation as a recA deletion strain. The cells are proficient in SOS induction, and results indicate the defect involves the capacity of RecA protein to participate directly in recombinational DNA repair. In vitro, the RecA423 protein binds to single-stranded DNA slowly, with an associated decline in the ATP hydrolytic activity. The RecA423 protein promoted a limited DNA strand exchange reaction when the DNA substrates were homologous, but no bypass of a short heterologous insert in the duplex DNA substrate was observed. These results indicate that poor binding to DNA and low ATP hydrolysis activity can selectively compromise certain functions of RecA protein. The RecA423 protein can promote recombination between homologous DNAs during Hfr crosses, indicating that the biochemical requirements for such genetic exchanges are minimal. However, the deficiencies in recombinational DNA repair suggest that the biochemical requirements for this function are more exacting.     

Biochemical interactions within a ternary complex of the bacteriophage T4 recombination proteins uvsY and gp32 bound to single-stranded DNA

The presynaptic phase of homologous recombination requires the formation of a filament of single-stranded DNA (ssDNA) coated with a recombinase enzyme. In bacteriophage T4, at least three proteins are required for the assembly of this presynaptic filament. In addition to the T4 recombinase, uvsX protein, the T4 ssDNA binding protein (gp32), and the uvsY recombination accessory protein are also required. Here we report on a detailed analysis of a tripartite filament containing ssDNA bound by stoichiometric quantities of both uvsY and gp32, which appears to be an important intermediate in the assembly of the T4 presynaptic filament. We demonstrate that uvsY and gp32 simultaneously co-occupy the ssDNA in a noncompetitive fashion. In addition, we show that protein-protein interactions between uvsY and gp32 are not required for the assembly of this ternary complex and do not affect the affinity of uvsY for the ssDNA lattice. Finally, we demonstrate that the interaction of gp32 with the ssDNA is destabilized within this complex, in a manner which is independent of gp32-uvsY interactions. The data suggest that the uvsY protein acts to remodel the gp32-ssDNA complex via uvsY-ssDNA interactions. The implications of these findings for the mechanism of presynapsis in the T4 recombination system are discussed.     

The preference for GT-rich DNA by the yeast Rad51 protein defines a set of universal pairing sequences

The Rad51 protein of Saccharomyces cerevisiae is a eukaryotic homolog of the RecA protein, the prototypic DNA strand-exchange protein of Escherichia coli. RAD51 gene function is required for efficient genetic recombination and for DNA double-strand break repair. Recently, we demonstrated that RecA protein has a preferential affinity for GT-rich DNA sequences-several of which exhibit enhanced RecA protein-promoted homologous pairing activity. The fundamental similarity between the RecA and Rad51 proteins suggests that Rad51 might display an analogous bias. Using in vitro selection, here we show that the yeast Rad51 protein shares the same preference for GT-rich sequences as its prokaryotic counterpart. This bias is also manifest as an increased ability of Rad51 protein to promote the invasion of supercoiled DNA by homologous GT-rich single-stranded DNA, an activity not previously described for the eukaryotic pairing protein. We propose that the preferred utilization of GT-rich sequences is a conserved feature among all homologs of RecA protein, and that GT-rich regions are loci for increased genetic exchange in both prokaryotes and eukaryotes.     

Asymmetric interactions of hexameric bacteriophage T7 DNA helicase with the 5'- and 3'-tails of the forked DNA substrate

Bacteriophage T7 DNA helicase requires two noncomplementary single-stranded DNA (ssDNA) tails next to a double-stranded DNA (dsDNA) region to initiate DNA unwinding. The interactions of the helicase with the DNA were investigated using a series of forked DNAs. Our results show that the helicase interacts asymmetrically with the two tails of the forked DNA. When the helicase was preassembled on the forked DNA before the start of unwinding, a DNA with 15-nucleotide (nt) 3'-tail and 35-nt 5'-tail was unwound with optimal rates close to 60 base pairs/s at 18 degrees C. When the helicase was not preassembled on the DNA, a >65-nt long 5'-tail was required for maximal unwinding rates of 12 base pairs/s. We show that the helicase interacts specifically with the ssDNA region and maintains contact with both ssDNA strands during DNA unwinding, since conversion of the two ssDNA tails to dsDNA structures greatly inhibited unwinding, and the helicase was unable to unwind past a nick in the dsDNA region. These studies have provided new insights into the mechanism of DNA unwinding. We propose an exclusion model of DNA unwinding in which T7 helicase hexamer interacts mainly with the ssDNA strands during DNA unwinding, encircling the 5'-strand and excluding the 3'-strand from the hole.     

The role of negative superhelicity and length of homology in the formation of paranemic joints promoted by RecA protein

Escherichia coli RecA protein pairs homologous DNA molecules to form paranemic joints when there is an absence of a free end in the region of homologous contact. Paranemic joints are a key intermediate in homologous recombination and are important in understanding the mechanism for a search of homology. The efficiency of paranemic joint formation depended on the length of homology and the topological forms of the duplex DNA. The presence of negative superhelicity increased the pairing efficiency and reduced the minimal length of homology required for paranemic joint formation. Negative superhelicity stimulated joint formation by favoring the initial unwinding of duplex DNA that occurred during the homology search and was not essential in the maintenance of the paired structure. Regardless of length of homology, formation of paranemic joints using circular duplex DNA required the presence of more than six negative supercoils. Above six negative turns, an increasing degree of negative superhelicity resulted in a linear increase in the pairing efficiency. These results support a model of two distinct kinds of DNA unwinding occurring in paranemic joint formation: an initial unwinding caused by heterologous contacts during synapsis and a later one during pairing of the homologous molecules.