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 lament, 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 > proximal joints >> 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 resutant 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.A model system that has proven useful in exploring the nature of recombination promoted by RecA protein consists of circular single-stranded DNA and duplex DNA, the latter usually in linear form (1,2). Studies ofthis model system have revealed the overall course of the reaction and some mechanistic aspects. The reaction has three major phases: (i) presynapsis, in which RecA protein polymerizes on singlestranded DNA to form a right-handed helical nucleoprotein filament; (ii) synapsis, during which naked duplex DNA first binds nonspecifically and weakly to sites on the nucleoprotein filament and then comes into homologous alignment; and (iii) strand exchange, which produces a new heteroduplex molecule and a displaced linear single strand.Strand exchange itself is directional, 5' to 3' with respect to the circular plus strand in the RecA filament or its displaced linear homolog, which defines a proximal and a distal end in the duplex DNA ( Fig. 1; refs. 1 and 2). Many observations have been reported that show, however, that the initial pairing event that produces a joint molecule is not polarized but rather can occur at the proximal 5' end of the plus strand, the distal 3' end, or in the middle of a linear duplex molecule (Fig. 1;. On the other hand, Konforti and Davis (6,7), studying the pairing of linear single strands with superhelical DNA as assayed by gel electrophoresis, found that when homology was limited to the 5' end of a linear plus strand, joints were scarcely detectable. Hsieh et al. (8) found that when homology was limited to very short sequences at the ends of duplex DNA, only distal joints, as defined above, were detectable by gel electrophoresis. Since strand exchange, which proceeds in the 5' to 3' direction, was previously ob...
