Mechanism of the concerted action of recA protein and helix-destabilizing proteins in homologous recombination

Ionic inhibition of formation of RecA nucleoprotein networks blocks homologous pairing

Conditions that favor the complete coating of single-stranded DNA by RecA protein promote the association of these presynaptic filaments with naked double-stranded DNA to form large nucleoprotein networks before homologous pairing occurs. These RecA nucleoprotein networks sequester virtually all of the DNA in the reaction mixture. Conditions that are suboptimal for the formation of the RecA presynaptic filament rendered both the formation of RecA-DNA networks and the subsequent formation of joint molecules sensitive to inhibition by excess ATP or by pyrophosphate when these were added during synapsis. The rate of homologous pairing was directly related to the degree of inhibition of network formation. Various multivalent cations added during synapsis restored both the formation of networks and the pairing of homologous molecules. These observations support the view that the nucleoprotein network is a synaptic intermediate by means of which RecA protein facilitates the conjunction of DNA molecules and the subsequent processive search for homology. Inhibition by multivalent anions and restoration by multivalent cations suggests in addition, that negative charge repulsion inhibits the binding of naked duplex DNA to presynaptic filaments.

Networks of DNA and RecA protein are intermediates in homologous pairing

Partial coating of single-stranded DNA by recA protein causes its aggregation, but conditions that promote complete coating inhibit independent aggregation of single strands and, instead, cause the mutually dependent conjunction of single- and double-stranded DNA in complexes that sediment at more than 10 000 S. This coaggregation is independent of homology but otherwise shares key properties of homologous pairing of single strands with duplex DNA: both processes require ATP, MgCl2, and stoichiometric amounts of recA protein; both are very sensitive to inhibition by salt and ADP. Coaggregates are closed domains that are intermediates in homologous pairing: they form faster than joint molecules, they include virtually all of the DNA in the reaction mixture, and they yield joint molecules nearly an order of magnitude faster than they exchange DNA molecules with the surrounding solution. The independent aggregation of single-stranded DNA differs in all respects except the requirement for Mg2+, and its properties correlate instead with those associated with the renaturation of complementary single strands by recA protein.

Kinetics of homologous pairing promoted by RecA protein: effects of ends and internal sites in DNA

When recA protein was preincubated with single-stranded DNA in the presence of an ATP-regenerating system prior to the addition of homologous duplex DNA, a slow presynaptic step was eliminated, and the subsequent homologous pairing was revealed as a reaction whose rate exceeds by 1 or 2 orders of magnitude the calculated rate of spontaneous renaturation in 0.15 M NaCl at Tm -25 degrees C. The pairing reaction displayed saturation kinetics with respect to both single-stranded and double-stranded DNA, indicating the existence of a rate-limiting enzyme-substrate complex. The signal observed in the assay of the pairing reaction was due to pairing at free homologous ends of the duplex DNA, as well as pairing in the middle of the duplex molecule, away from a free end. The apparent rate of pairing of circular single strands with linear duplex DNA was equal to the sum of the rates of pairing at sites located at either end of the duplex DNA or at interior sites, but the apparent rates attributable to ends were greater, and nicks also stimulated the apparent rate.

Isolation and visualization of active presynaptic filaments of recA protein and single-stranded DNA

In the presence of ATP, recA protein forms a presynaptic complex with single-stranded DNA that is an obligatory intermediate in homologous pairing. Presynaptic complexes of recA protein and circular single strands that are active in forming joint molecules can be isolated by gel filtration. These isolated active complexes are nucleoprotein filaments with the following characteristics: (i) a contour length that is at least 1.5 times that of the corresponding duplex DNA molecule, (ii) an ordered structure visualized by negative staining as a striated filament with a repeat distance of 9.0 nm and a width of 9.3 nm, (iii) approximately 8 molecules of recA protein and 20 nucleotide residues per striation. The widened spacing between bases in the nucleoprotein filament means that the initial matching of complementary sequences must involve intertwining of the filament and duplex DNA, unwinding of the latter, or some combination of both to equalize the spacing between nascent base pairs. These experiments support the concept that recA protein first forms a filament with single-stranded DNA, which in turn binds to duplex DNA to mediate both homologous pairing and subsequent strand exchange.