Identification of the RecA protein-loading domain of RecBCD enzyme.

Genetic recombination in Escherichia coli is stimulated by the recombination hotspot Chi (chi), a regulatory element that modifies the activities of the RecBCD enzyme and leads to loading of the DNA strand exchange protein, RecA, onto the chi-containing DNA strand. The RecBC enzyme, which lacks the RecD subunit, loads RecA protein constitutively, in a manner that is independent of chi. Using a truncated RecBC enzyme lacking the 30 kDa C-terminal domain of the RecB subunit, we show that this domain is necessary for RecA protein-loading. We propose that this domain harbors a site that interacts with RecA protein, recruiting it to single-stranded DNA during unwinding. This ability of a translocating enzyme to deliver material (RecA protein) to a specific target site (the chi sequence) parallels that of other cellular motor proteins.

A single mutation, RecB(D1080A,) eliminates RecA protein loading but not Chi recognition by RecBCD enzyme.

Homologous recombination and double-stranded DNA break repair in Escherichia coli are initiated by the multifunctional RecBCD enzyme. After binding to a double-stranded DNA end, the RecBCD enzyme unwinds and degrades the DNA processively. This processing is regulated by the recombination hot spot, Chi (chi: 5'-GCTGGTGG-3'), which induces a switch in the polarity of DNA degradation and activates RecBCD enzyme to coordinate the loading of the DNA strand exchange protein, RecA, onto the single-stranded DNA products of unwinding. Recently, a single mutation in RecB, Asp-1080 --> Ala, was shown to create an enzyme (RecB(D1080A)CD) that is a processive helicase but not a nuclease. Here we show that the RecB(D1080A)CD enzyme is also unable to coordinate the loading of the RecA protein, regardless of whether chi sites are present in the DNA. However, the RecB(D1080A)CD enzyme does respond to chi sites by inactivating in a chi-dependent manner. These data define a locus of the RecBCD enzyme that is essential not only for nuclease function but also for the coordination of RecA protein loading.

The RecBC enzyme loads RecA protein onto ssDNA asymmetrically and independently of chi, resulting in constitutive recombination activation.

Double-strand DNA break repair and homologous recombination in Escherichia coli proceed by the RecBCD pathway, which is regulated by cis-acting elements known as chi sites. A crucial feature of this regulation is the RecBCD enzyme-directed loading of RecA protein specifically onto the 3'-terminal, chi-containing DNA strand. Here we show that RecBC enzyme (lacking the RecD subunit) loads RecA protein constitutively onto the 3'-terminal DNA strand, with no requirement for chi. This strand is preferentially utilized in homologous pairing reactions. We propose that RecA protein loading is a latent property of the RecBCD holoenzyme, which is normally blocked by the RecD subunit and is revealed following interaction with chi.

Chi-activated RecBCD enzyme possesses 5'-->3' nucleolytic activity, but RecBC enzyme does not: evidence suggesting that the alteration induced by Chi is not simply ejection of the RecD subunit.

BACKGROUND: Homologous recombination in Escherichia coli is initiated by the RecBCD enzyme, and is stimulated by DNA elements known as Chi (chi) sites. The RecBCD enzyme is both a helicase and a nuclease. Recognition of chi causes both attenuation of the 3'-->5' exonuclease activity of the RecBCD enzyme, and activation of an exonuclease activity with 5'-->3' polarity, while leaving the helicase activity unaffected. A variety of evidence suggests that chi-recognition by RecBCD enzyme is accompanied by ejection of the RecD subunit. RESULTS: Through examination of RecBCD exonuclease activity under a variety of conditions, we have shown that recognition of chi by the RecBCD enzyme results in a net reduction of nuclease activity. In addition, the exact location of the first cleavage event elicited by chi-activation of the 5'-->3' nuclease is dependent upon the concentration of free magnesium ions. Finally, we have demonstrated that purified RecBC enzyme (i.e. without the RecD subunit) possesses no significant exonuclease activity under conditions where the chi-modified RecBCD enzyme is an active 5'-->3' exonuclease. CONCLUSIONS: We have shown that, despite the activation of a 5'-->3' exonuclease, recognition of chi by the RecBCD enzyme results in a net preservation of DNA. This new chi-activated nucleolytic action shows surprising variability in the exact location of its initial cleavage. We have demonstrated that purified RecBC enzyme is not an exact analogue of the chi-activated RecBCD enzyme, suggesting that the biochemical basis of chi-activation is not simply ejection of the RecD subunit.

Reversible inactivation of the Escherichia coli RecBCD enzyme by the recombination hotspot chi in vitro: evidence for functional inactivation or loss of the RecD subunit.

Genetic recombination in Escherichia coli is stimulated by a RecBCD enzyme-mediated event at DNA sequences known as Chi (chi) sites (5'-GCTGGTGG-3'). Previously, it was shown that chi acts to regulate the nuclease activity of RecBCD; here, we demonstrate that, under appropriate conditions, interaction with chi sites can also result in an inactivation of helicase activity of RecBCD. The unwinding of double-stranded DNA-containing chi sites, under conditions of limiting Mg2+ ion, results in the reversible inactivation of RecBCD; addition of excess Mg2+ to the reaction reactivates all activities of RecBCD. Inactivation is the consequence of a chi-dependent modification of RecBCD that appears to result from an inability of the chi-modified RecBCD to reinitiate unwinding of intact DNA molecules. This characteristic behavior of RecBCD and chi is displayed by the reconstituted RecBC (i.e., without the RecD subunit), except that it is not dependent on chi interaction. This biochemical similarity between the chi-modified RecBCD and RecBC enzymes implies that recognition of chi results in a dissociation or functional inactivation of RecD subunit and lends support to the hypothesis that interaction with chi results in ejection of the RecD subunit.