A unified mechanism for the nuclease and unwinding activities of the recBC enzyme of Escherichia coli

RecBCD enzyme: mechanistic insights from mutants of a complex helicase-nuclease

SUMMARYRecBCD enzyme is a multi-functional protein that initiates the major pathway of homologous genetic recombination and DNA double-strand break repair in Escherichia coli. It is also required for high cell viability and aids proper DNA replication. This 330-kDa, three-subunit enzyme is one of the fastest, most processive helicases known and contains a potent nuclease controlled by Chi sites, hotspots of recombination, in DNA. RecBCD undergoes major changes in activity and conformation when, during DNA unwinding, it encounters Chi (5'-GCTGGTGG-3') and nicks DNA nearby. Here, we discuss the multitude of mutations in each subunit that affect one or another activity of RecBCD and its control by Chi. These mutants have given deep insights into how the multiple activities of this complex enzyme are coordinated and how it acts in living cells. Similar studies could help reveal how other complex enzymes are controlled by inter-subunit interactions and conformational changes.

Single-molecule insight into stalled replication fork rescue in Escherichia coli

DNA replication forks stall at least once per cell cycle in Escherichia coli. DNA replication must be restarted if the cell is to survive. Restart is a multi-step process requiring the sequential action of several proteins whose actions are dictated by the nature of the impediment to fork progression. When fork progress is impeded, the sequential actions of SSB, RecG and the RuvABC complex are required for rescue. In contrast, when a template discontinuity results in the forked DNA breaking apart, the actions of the RecBCD pathway enzymes are required to resurrect the fork so that replication can resume. In this review, we focus primarily on the significant insight gained from single-molecule studies of individual proteins, protein complexes, and also, partially reconstituted regression and RecBCD pathways. This insight is related to the bulk-phase biochemical data to provide a comprehensive review of each protein or protein complex as it relates to stalled DNA replication fork rescue.

Fidelity of prespacer capture and processing is governed by the PAM-mediated interactions of Cas1-2 adaptation complex in CRISPR-Cas type I-E system

Prokaryotes deploy CRISPR-Cas-based RNA-guided adaptive immunity to fend off mobile genetic elements such as phages and plasmids. During CRISPR adaptation, which is the first stage of CRISPR immunity, the Cas1-2 integrase complex captures invader-derived prespacer DNA and specifically integrates it at the leader-repeat junction as spacers. For this integration, several variants of CRISPR-Cas systems use Cas4 as an indispensable nuclease for selectively processing the protospacer adjacent motif (PAM) containing prespacers to a defined length. Surprisingly, however, a few CRISPR-Cas systems, such as type I-E, are bereft of Cas4. Despite the absence of Cas4, how the prespacers show impeccable conservation for length and PAM selection in type I-E remains intriguing. Here, using in vivo and in vitro integration assays, deep sequencing, and exonuclease footprinting, we show that Cas1-2/I-E-via the type I-E-specific extended C-terminal tail of Cas1-displays intrinsic affinity for PAM containing prespacers of variable length in Escherichia coli Although Cas1-2/I-E does not prune the prespacers, its binding protects the prespacer boundaries from exonuclease action. This ensures the pruning of exposed ends by exonucleases to aptly sized substrates for integration into the CRISPR locus. In summary, our work reveals that in a few CRISPR-Cas variants, such as type I-E, the specificity of PAM selection resides with Cas1-2, whereas the prespacer processing is co-opted by cellular non-Cas exonucleases, thereby offsetting the need for Cas4.

CRISPR-Cas adaptation in Escherichia coli requires RecBCD helicase but not nuclease activity, is independent of homologous recombination, and is antagonized by 5' ssDNA exonucleases

Prokaryotic adaptive immunity is established against mobile genetic elements (MGEs) by ‘naïve adaptation’ when DNA fragments from a newly encountered MGE are integrated into CRISPR–Cas systems. In Escherichia coli, DNA integration catalyzed by Cas1–Cas2 integrase is well understood in mechanistic and structural detail but much less is known about events prior to integration that generate DNA for capture by Cas1–Cas2. Naïve adaptation in E. coli is thought to depend on the DNA helicase-nuclease RecBCD for generating DNA fragments for capture by Cas1–Cas2. The genetics presented here show that naïve adaptation does not require RecBCD nuclease activity but that helicase activity may be important. RecA loading by RecBCD inhibits adaptation explaining previously observed adaptation phenotypes that implicated RecBCD nuclease activity. Genetic analysis of other E. coli nucleases and naïve adaptation revealed that 5′ ssDNA tailed DNA molecules promote new spacer acquisition. We show that purified E. coli Cas1–Cas2 complex binds to and nicks 5′ ssDNA tailed duplexes and propose that E. coli Cas1–Cas2 nuclease activity on such DNA structures supports naïve adaptation.

RecG Directs DNA Synthesis during Double-Strand Break Repair

Homologous recombination provides a mechanism of DNA double-strand break repair (DSBR) that requires an intact, homologous template for DNA synthesis. When DNA synthesis associated with DSBR is convergent, the broken DNA strands are replaced and repair is accurate. However, if divergent DNA synthesis is established, over-replication of flanking DNA may occur with deleterious consequences. The RecG protein of Escherichia coli is a helicase and translocase that can re-model 3-way and 4-way DNA structures such as replication forks and Holliday junctions. However, the primary role of RecG in live cells has remained elusive. Here we show that, in the absence of RecG, attempted DSBR is accompanied by divergent DNA replication at the site of an induced chromosomal DNA double-strand break. Furthermore, DNA double-stand ends are generated in a recG mutant at sites known to block replication forks. These double-strand ends, also trigger DSBR and the divergent DNA replication characteristic of this mutant, which can explain over-replication of the terminus region of the chromosome. The loss of DNA associated with unwinding joint molecules previously observed in the absence of RuvAB and RecG, is suppressed by a helicase deficient PriA mutation (priA300), arguing that the action of RecG ensures that PriA is bound correctly on D-loops to direct DNA replication rather than to unwind joint molecules. This has led us to put forward a revised model of homologous recombination in which the re-modelling of branched intermediates by RecG plays a fundamental role in directing DNA synthesis and thus maintaining genomic stability.

How RecBCD enzyme and Chi promote DNA break repair and recombination: a molecular biologist's view

The repair of DNA double-strand breaks (DSBs) is essential for cell viability and important for homologous genetic recombination. In enteric bacteria such as Escherichia coli, the major pathway of DSB repair requires the RecBCD enzyme, a complex helicase-nuclease regulated by a simple unique DNA sequence called Chi. How Chi regulates RecBCD has been extensively studied by both genetics and biochemistry, and two contrasting mechanisms to generate a recombinogenic single-stranded DNA tail have been proposed: the nicking of one DNA strand at Chi versus the switching of degradation from one strand to the other at Chi. Which of these reactions occurs in cells has remained unproven because of the inability to detect intracellular DNA intermediates in bacterial recombination and DNA break repair. Here, I discuss evidence from a combination of genetics and biochemistry indicating that nicking at Chi is the intracellular (in vivo) reaction. This example illustrates the need for both types of analysis (i.e., molecular biology) to uncover the mechanism and control of complex processes in living cells.

Recombination hotspots and single-stranded DNA binding proteins couple DNA translocation to DNA unwinding by the AddAB helicase-nuclease

AddAB is a helicase-nuclease that processes double-stranded DNA breaks for repair by homologous recombination. This process is modulated by Chi recombination hotspots: specific DNA sequences that attenuate the nuclease activity of the translocating AddAB complex to promote downstream recombination. Using a combination of kinetic and imaging techniques, we show that AddAB translocation is not coupled to DNA unwinding in the absence of single-stranded DNA binding proteins because nascent single-stranded DNA immediately re-anneals behind the moving enzyme. However, recognition of recombination hotspot sequences during translocation activates unwinding by coupling these activities, thereby ensuring the downstream formation of single-stranded DNA that is required for RecA-mediated recombinational repair. In addition to their implications for the mechanism of double-stranded DNA break repair, these observations may affect our implementation and interpretation of helicase assays and our understanding of helicase mechanisms in general.

Genetic requirements for high constitutive SOS expression in recA730 mutants of Escherichia coli

The RecA protein in its functional state is in complex with single-stranded DNA, i.e., in the form of a RecA filament. In SOS induction, the RecA filament functions as a coprotease, enabling the autodigestion of the LexA repressor. The RecA filament can be formed by different mechanisms, but all of them require three enzymatic activities essential for the processing of DNA double-stranded ends. These are helicase, 5'-3' exonuclease, and RecA loading onto single-stranded DNA (ssDNA). In some mutants, the SOS response can be expressed constitutively during the process of normal DNA metabolism. The RecA730 mutant protein is able to form the RecA filament without the help of RecBCD and RecFOR mediators since it better competes with the single-strand binding (SSB) protein for ssDNA. As a consequence, the recA730 mutants show high constitutive SOS expression. In the study described in this paper, we studied the genetic requirements for constitutive SOS expression in recA730 mutants. Using a β-galactosidase assay, we showed that the constitutive SOS response in recA730 mutants exhibits different requirements in different backgrounds. In a wild-type background, the constitutive SOS response is partially dependent on RecBCD function. In a recB1080 background (the recB1080 mutation retains only helicase), constitutive SOS expression is partially dependent on RecBCD helicase function and is strongly dependent on RecJ nuclease. Finally, in a recB-null background, the constitutive SOS expression of the recA730 mutant is dependent on the RecJ nuclease. Our results emphasize the importance of the 5'-3' exonuclease for high constitutive SOS expression in recA730 mutants and show that RecBCD function can further enhance the excellent intrinsic abilities of the RecA730 protein in vivo.

RecBCD enzyme and the repair of double-stranded DNA breaks

The RecBCD enzyme of Escherichia coli is a helicase-nuclease that initiates the repair of double-stranded DNA breaks by homologous recombination. It also degrades linear double-stranded DNA, protecting the bacteria from phages and extraneous chromosomal DNA. The RecBCD enzyme is, however, regulated by a cis-acting DNA sequence known as Chi (crossover hotspot instigator) that activates its recombination-promoting functions. Interaction with Chi causes an attenuation of the RecBCD enzyme's vigorous nuclease activity, switches the polarity of the attenuated nuclease activity to the 5' strand, changes the operation of its motor subunits, and instructs the enzyme to begin loading the RecA protein onto the resultant Chi-containing single-stranded DNA. This enzyme is a prototypical example of a molecular machine: the protein architecture incorporates several autonomous functional domains that interact with each other to produce a complex, sequence-regulated, DNA-processing machine. In this review, we discuss the biochemical mechanism of the RecBCD enzyme with particular emphasis on new developments relating to the enzyme's structure and DNA translocation mechanism.

RecBCD enzyme switches lead motor subunits in response to chi recognition

RecBCD is a DNA helicase comprising two motor subunits, RecB and RecD. Recognition of the recombination hotspot, chi, causes RecBCD to pause and reduce translocation speed. To understand this control of translocation, we used single-molecule visualization to compare RecBCD to the RecBCD(K177Q) mutant with a defective RecD motor. RecBCD(K177Q) paused at chi but did not change its translocation velocity. RecBCD(K177Q) translocated at the same rate as the wild-type post-chi enzyme, implicating RecB as the lead motor after chi. P1 nuclease treatment eliminated the wild-type enzyme's velocity changes, revealing a chi-containing ssDNA loop preceding chi recognition and showing that RecD is the faster motor before chi. We conclude that before chi, RecD is the lead motor but after chi, the slower RecB motor leads, implying a switch in motors at chi. We suggest that degradation of foreign DNA needs fast translocation, whereas DNA repair uses slower translocation to coordinate RecA loading onto ssDNA.

Kinetics of ATP-stimulated nuclease activity of the Escherichia coli RecBCD enzyme

The RecBCD enzyme is an ATP-dependent nuclease on both single-stranded and double-stranded DNA substrates. We have investigated the kinetics of the RecBCD-catalyzed reaction with small, single-stranded oligodeoxyribonucleotide substrates under single-turnover conditions using rapid-quench flow techniques. RecBCD-DNA complexes were allowed to form in pre-incubation mixtures. The nuclease reactions were initiated by mixing with ATP. The reaction time-courses were fit to several possible reaction mechanisms and quantitative estimates were obtained for rate constants for individual reaction steps. The relative rates of forward reaction versus dissociation from the DNA, and the fact that inclusion of excess non-radiolabeled single-stranded DNA to trap free RecBCD has no effect on the nuclease reaction, indicates that the reaction is processive. The reaction products show that the reaction begins near the 3'-end of the [5'-32P]DNA substrates and the major cleavage sites are two to four phosphodiester bonds apart. The product distribution is unchanged as the ATP concentration varies from 10 microM to 100 microM ATP, while the overall reaction rate varies by about tenfold. These observations suggest that DNA cleavage is tightly coordinated with movement of the enzyme along the DNA. The reaction time-courses at low concentrations of ATP (10 microM and 25 microM) have a significant lag before cleavage products appear. We propose that the lag represents ATP-dependent movement of the DNA from an initial binding site in the helicase domain of the RecB subunit to the nuclease active site in a separate domain of RecB. The extent of reaction of the substrate is limited (approximately 50%) under all conditions. This may indicate the formation of a non-productive RecBCD-DNA complex that does not dissociate in the 1-2 s time-scale of our experiments.

Effects of temperature and ATP on the kinetic mechanism and kinetic step-size for E.coli RecBCD helicase-catalyzed DNA unwinding

The kinetic mechanism by which Escherichia coli RecBCD helicase unwinds duplex DNA was studied using a fluorescence stopped-flow method. Single turnover DNA unwinding experiments were performed using a series of fluorescently labeled DNA substrates containing duplex DNA regions ranging from 24 bp to 60 bp. All or no DNA unwinding time courses were obtained by monitoring the changes in fluorescence resonance energy transfer between a Cy3 donor and Cy5 acceptor fluorescent pair placed on opposite sides of a nick in the duplex DNA. From these experiments one can determine the average rates of DNA unwinding as well as a kinetic step-size, defined as the average number of base-pairs unwound between two successive rate-limiting steps repeated during DNA unwinding. In order to probe how the kinetic step-size might relate to a mechanical step-size, we performed single turnover experiments as a function of [ATP] and temperature. The apparent unwinding rate constant, kUapp, decreases with decreasing [ATP], exhibiting a hyperbolic dependence on [ATP] (K1/2=176(+/-30) microM) and a maximum rate of kUapp=204(+/-4) steps s(-1) (mkUapp=709(+/-14) bp s(-1)) (10 mM MgCl2, 30 mM NaCl (pH 7.0), 5% (v/v) glycerol, 25.0 degrees C). kUapp also increases with increasing temperature (10-25 degrees C), with Ea=19(+/-1) kcal mol(-1). However, the average kinetic step-size, m=3.9(+/-0.5) bp step(-1), remains independent of [ATP] and temperature. This indicates that even though the values of the rate constants change, the same elementary kinetic step in the unwinding cycle remains rate-limiting over this range of conditions and this kinetic step remains coupled to ATP binding. The implications of the constancy of the measured kinetic step-size for the mechanism of RecBCD-catalyzed DNA unwinding are discussed.

RecFOR function is required for DNA repair and recombination in a RecA loading-deficient recB mutant of Escherichia coli

The RecA loading activity of the RecBCD enzyme, together with its helicase and 5' --> 3' exonuclease activities, is essential for recombination in Escherichia coli. One particular mutant in the nuclease catalytic center of RecB, i.e., recB1080, produces an enzyme that does not have nuclease activity and is unable to load RecA protein onto single-stranded DNA. There are, however, previously published contradictory data on the recombination proficiency of this mutant. In a recF(-) background the recB1080 mutant is recombination deficient, whereas in a recF(+) genetic background it is recombination proficient. A possible explanation for these contrasting phenotypes may be that the RecFOR system promotes RecA-single-strand DNA filament formation and replaces the RecA loading defect of the RecB1080CD enzyme. We tested this hypothesis by using three in vivo assays. We compared the recombination proficiencies of recB1080, recO, recR, and recF single mutants and recB1080 recO, recB1080 recR, and recB1080 recF double mutants. We show that RecFOR functions rescue the repair and recombination deficiency of the recB1080 mutant and that RecA loading is independent of RecFOR in the recB1080 recD double mutant where this activity is provided by the RecB1080C(D(-)) enzyme. According to our results as well as previous data, three essential activities for the initiation of recombination in the recB1080 mutant are provided by different proteins, i.e., helicase activity by RecB1080CD, 5' --> 3' exonuclease by RecJ- and RecA-single-stranded DNA filament formation by RecFOR.

DNA unwinding step-size of E. coli RecBCD helicase determined from single turnover chemical quenched-flow kinetic studies

The mechanism by which Escherichia coli RecBCD DNA helicase unwinds duplex DNA was examined in vitro using pre-steady-state chemical quenched-flow kinetic methods. Single turnover DNA unwinding experiments were performed by addition of ATP to RecBCD that was pre-bound to a series of DNA substrates containing duplex DNA regions ranging from 24 bp to 60 bp. In each case, the time-course for formation of completely unwound DNA displayed a distinct lag phase that increased with duplex length, reflecting the transient formation of partially unwound DNA intermediates during unwinding catalyzed by RecBCD. Quantitative analysis of five independent sets of DNA unwinding time courses indicates that RecBCD unwinds duplex DNA in discrete steps, with an average unwinding "step-size", m=3.9(+/-1.3)bp step(-1), with an average unwinding rate of k(U)=196(+/-77)steps s(-1) (mk(U)=790(+/-23)bps(-1)) at 25.0 degrees C (10mM MgCl(2), 30 mM NaCl (pH 7.0), 5% (v/v) glycerol). However, additional steps, not linked directly to DNA unwinding are also detected. This kinetic DNA unwinding step-size is similar to that determined for the E.coli UvrD helicase, suggesting that these two SF1 superfamily helicases may share similar mechanisms of DNA unwinding.

Progressive loss of lambda prophage recombinogenicity in UV-irradiated Escherichia coli: the role of RecBCD enzyme

RecBCD enzyme is involved in the radiation-induced process known as prophage inactivation. The process leads to the inability of lambda prophage to excise itself from the Escherichia coli chromosome via site-specific recombination. In this work we sought to further characterize the role of RecBCD enzyme in this process. In addition, we examined the ability of irradiated prophage to recombine with the infecting homologous phage. We used several E. coli mutants differentially altered in RecBCD's activities. The results showed that in the mutants carrying either recB2109 or recD1903, which do not exhibit significant nuclease activities, the prophage progressively loses its capacity for both site-specific and general recombination. In the recB268 null mutant, however, prophage recombinogenicity remained fully preserved. We also showed that the prophage unable to recombine retained its ability to complement the mutant infecting phage and that the recombination frequencies in phage x phage crosses were not affected by postirradiation incubation. Our results suggest that the helicase activity of RecBCD is responsible for the progressive loss of prophage recombinogenicity. This loss is most probably a consequence of the unsuccessful RecBCD-dependent recombinational repair of double-stranded breaks in the cell chromosome, during which some structures unsuitable for further recombination reactions may be produced.

In vivo studies of the Escherichia coli RecB polypeptide lacking its nuclease center

In vitro, RecB1-929, the truncated Escherichia coli RecB polypeptide, comprising the N-terminal (helicase) domain of RecB, can combine with RecC and RecD subunits of RecBCD enzyme. The resulting RecB1-929CD heterotrimer is a potent helicase; due to the loss of the nuclease center of RecB, it is devoid of DNase activities. By making use of the RecB1-929-producing plasmid pMY100, the in vivo behavior of this truncated polypeptide was studied. The following observations were made. (i) Large amounts of RecB1-929 in the pulse-heated lambdacI857gam+ lysogens prevented the growth of a gene 2 mutant of bacteriophage T4. It may be inferred that lambda-Gam protein, which otherwise inhibits RecBCD DNase and thus permits the growth of this phage, is bound by the helicase domain of RecB. (ii) The simultaneous presence of RecB1-929, RecC, and RecD did not restore recombination proficiency and ultraviolet resistance of recB cells. (iii) The presence of RecB1-929 did not alter recombination and repair processes in wild-type (recBCD+) cells. Even excessively large amounts of this truncated polypeptide did not reduce degradation of chromosomal DNA damaged by y-rays. It may be inferred that under in vivo conditions, the 30-kDa domain of RecB is essential for assembly of the RecBCD enzyme and/or for holding its three subunits together.

A single nuclease active site of the Escherichia coli RecBCD enzyme catalyzes single-stranded DNA degradation in both directions

The RecBCD enzyme of Escherichia coli is an ATP-dependent DNA exonuclease and a helicase. Its exonuclease activity is subject to regulation by an octameric nucleotide sequence called chi. In this study, site-directed mutations were made in the carboxyl-terminal nuclease domain of the RecB subunit, and their effects on RecBCD's enzymatic activities were investigated. Mutation of two amino acid residues, Asp(1067) and Lys(1082), abolished nuclease activity on both single- and double-stranded DNA. Together with Asp(1080), these residues compose a motif that is similar to one shown to form the active site of several restriction endonucleases. The nuclease reactions catalyzed by the RecBCD enzyme should therefore follow the same mechanism as these restriction endonucleases. Furthermore, the mutant enzymes were unable to produce chi-specific fragments that are thought to result from the 3'-5' and 5'-3' single-stranded exonuclease activities of the enzyme during its reaction with chi-containing double-stranded DNA. The results show that the nuclease active site in the RecB C-terminal 30-kDa domain is the universal nuclease active site of RecBCD that is responsible for DNA degradation in both directions during the reaction with double-stranded DNA. A novel explanation for the observed nuclease polarity switch and RecBCD-DNA interaction is offered.

Recombinational repair of DNA damage in Escherichia coli and bacteriophage lambda

Although homologous recombination and DNA repair phenomena in bacteria were initially extensively studied without regard to any relationship between the two, it is now appreciated that DNA repair and homologous recombination are related through DNA replication. In Escherichia coli, two-strand DNA damage, generated mostly during replication on a template DNA containing one-strand damage, is repaired by recombination with a homologous intact duplex, usually the sister chromosome. The two major types of two-strand DNA lesions are channeled into two distinct pathways of recombinational repair: daughter-strand gaps are closed by the RecF pathway, while disintegrated replication forks are reestablished by the RecBCD pathway. The phage lambda recombination system is simpler in that its major reaction is to link two double-stranded DNA ends by using overlapping homologous sequences. The remarkable progress in understanding the mechanisms of recombinational repair in E. coli over the last decade is due to the in vitro characterization of the activities of individual recombination proteins. Putting our knowledge about recombinational repair in the broader context of DNA replication will guide future experimentation.

Isolation and characterization of the C-terminal nuclease domain from the RecB protein of Escherichia coli

The RecB subunit of the Escherichia coli RecBCD enzyme has been shown in previous work to have two domains: an N-terminal 100 kDa domain with ATP-dependent helicase activity, and a C-terminal 30 kDa domain. The 30 kDa domain had nuclease activity when linked to a heterologous DNA binding protein, but by itself it appeared unable to bind DNA and lacked detectable nuclease activity. We have expressed and isolated this 30 kDa domain, called RecB(N), and show that it does have nuclease activity detectable at high protein concentration in the presence of polyethylene glycol, added as a molecular crowding agent. The activity is undetectable in a mutant RecB(N)protein in which an aspartate residue has been changed to alanine. Structural analysis of the wild-type and mutant RecB(N)proteins by second derivative absorbance and circular dichroism spectroscopy indicates that both are folded proteins with very similar secondary and tertiary structures. The results show that the Asp-->Ala mutation has not caused a significant structural change in the isolated domain and they support the conclusion that the C-terminal domain of RecB has the sole nuclease active site of RecBCD.

Identification of the nuclease active site in the multifunctional RecBCD enzyme by creation of a chimeric enzyme

The recombinational hot spot chi modulates the nuclease and helicase activities of the RecBCD enzyme, leading to generation of an early DNA intermediate for homologous recombination. Here we identify the subunit location of the nuclease active site in RecBCD. The isolated RecB protein cleaves circular single-stranded M13 phage DNA, but RecB1-929, comprising only the 100 kDa N-terminal domain of RecB, does not. We reported previously that the reconstituted RecB1-929CD enzyme also is not a nuclease, suggesting that the C-terminal 30 kDa domain of RecB is a non-specific ssDNA endonuclease. However, we were unable to detect nuclease activity with the subtilisin-generated C-terminal 30 kDa fragment of RecB. Since the subtilisin-generated fragment did not bind to a ssDNA-agarose column, we designed a chimeric enzyme by attaching the C-terminal 30 kDa domain of RecB to the gene 32 protein of T4 phage, a ssDNA binding protein that does not have strand scission ability. In addition, Asp427 in the chimeric enzyme (Asp1080 in RecB), a residue that is conserved among several RecB homologs, was substituted to alanine (the D427A mutant). The wild-type chimeric enzyme cleaves the M13 DNA and the D427A mutation abolishes the endonuclease activity of the chimeric enzyme but does not affect its DNA binding ability. This finding indicates an unusual bipartite nature in the structural organization of RecB, in which the DNA-binding function is located in the N-terminal 100 kDa domain and the nuclease catalytic domain is located in the C-terminal 30 kDa domain. The purified RecBD1080ACD mutant is a processive helicase but not a nuclease, demonstrating that RecBCD has a single nuclease active site in the C-terminal 30 kDa domain of RecB.

SSB protein controls RecBCD enzyme nuclease activity during unwinding: a new role for looped intermediates

The RecBCD enzyme of Escherichia coli initiates homologous recombination by unwinding and simultaneously degrading DNA from a double-stranded DNA end. Single-stranded DNA loops are intermediates of this unwinding process. Here we show that SSB protein reduces the level of DNA degradation by RecBCD enzyme during unwinding, by binding to these ssDNA intermediates. Prior to interaction with the recombination hot spot chi, RecBCD enzyme has both 3'-->5' exonuclease and a weaker 5'-->3' exonuclease activity. We show that degradation of the 5'-terminal strand at the entry site is much more extensive in the absence of SSB protein. After interaction with chi, the level of 5'-->3' exonuclease activity is increased; as expected, degradation of the 5'-strand is also elevated in the absence of SSB protein. Furthermore, we show that, in the absence of SSB protein, the RecBCD enzyme is inhibited by the ssDNA products of unwinding; SSB protein alleviates this inhibition. These results provide insight into the organization of helicase and nuclease domains within the RecBCD enzyme, and also suggest a new level at which the nuclease activity of RecBCD enzyme is controlled. Hence, they offer new insight into the role of SSB protein in the initiation phase of recombination.

The reduced levels of chi recognition exhibited by the RecBC1004D enzyme reflect its recombination defect in vivo

Homologous recombination in Escherichia coli is initiated by the RecBCD enzyme and is stimulated by an 8-nucleotide element known as Chi (chi). We present a detailed biochemical characterization of a mutant RecBCD enzyme, designated RecBC1004D, that displays a reduced level of chi site recognition. Initially characterized genetically as unable to respond to the chi sequence, we provide evidence to indicate that the ability of this mutant enzyme to respond to chi is reduced rather than lost; the mutant displays about 20-fold lower chi recognition than wild-type RecBCD enzyme. Although this enzyme exhibits wild-type levels of double-stranded DNA exonuclease, helicase, and ATPase activity, its ability to degrade single-stranded DNA is enhanced 2-3-fold. The data presented here suggest that the reduced recombination proficiency of the recBC1004D strain observed in vivo results from a basal level of modification of the RecBC1004D enzyme at both chi-specific, as well as nonspecific, DNA sequences.

Functions of the ATP hydrolysis subunits (RecB and RecD) in the nuclease reactions catalyzed by the RecBCD enzyme from Escherichia coli

The RecBCD enzyme from Escherichia coli is an ATP-dependent nuclease and helicase. Two of its subunits, the RecB and RecD proteins, are DNA-dependent ATPases. We have purified RecB and RecD proteins with mutations in their consensus ATP binding sites to study the functions of these subunits in the ATP-dependent nuclease activities of RecBCD. Reconstituted heterotrimeric enzymes were prepared by mixing wild-type RecB or RecB-K29Q mutant protein (RecB*) with purified RecC protein, and with a histidine-tagged wild-type RecD (hD) or mutant hRecD-K177Q (hD*) protein. RecBCD and all four reconstituted enzymes (wild-type, two single mutants, and the double mutant) cleave a single-stranded DNA oligomer substrate (25-mer) in the absence of ATP at rates of 0.03 to 0.06 min-1. The nuclease reaction catalyzed by RecB*ChD* is not stimulated significantly by ATP, while the reactions catalyzed by RecBCD, RecBChD, RecBChD*, and RecB*ChD are 300 to 3000 fold faster in the presence of 0.5 mM ATP. RecB*ChD* also has very low ATP hydrolysis activity (approximately 10(3)-fold less than RecBCD), as do the individual mutant RecB* and hRecD* proteins (approximately 100-fold less than RecB or hRecD). The products from the ATP-stimulated nuclease reaction with the oligomer substrate suggest a mechanism where two DNA molecules bind to the enzyme in opposite orientations and are cleaved by the nuclease active site. Cleavage towards the 3'-end of one oligomer (observed with RecBChD*) depends on the wild-type RecB subunit, while RecD-dependent cleavage (observed with RecB*ChD) occurs towards the 5'-end of the second bound oligomer.

Salt-stable complexes of the Escherichia coli RecBCD enzyme bound to double-stranded DNA

We have examined binding of the RecBCD enzyme to linear double-stranded DNA under two types of conditions. Binding in the absence of ATP can be measured by a nitrocellulose filter binding assay or by gel retardation on polyacrylamide gels. The binding is tightest to ends with four-nucleotide single-stranded 3'-termini (3'-overhang > 5'-overhang > blunt ends). The Kd for blunt ends is 3. 0 (+/-0.5) nM, in 50 mM Tris-HCl, pH 7.5, 10 mM MgCl2. The binding is weakened in the presence of NaCl, with none detected at 0.5 M NaCl. Binding in the presence of ATP and low MgCl2 concentrations ("unwinding conditions") can be measured by the filter assay and on agarose gels. Enzyme-DNA complexes allowed to form under unwinding conditions are not affected by 0.5 M NaCl. ATP hydrolysis continues and the complexes dissociate at a rate similar to those to which no salt is added. These enzyme-DNA complexes can be trapped with EDTA, and they are unaffected for at least 1 h by 0.5 M NaCl or heparin. The results show that the enzyme-DNA interactions are different when the enzyme is bound to partially unwound DNA compared to when it is bound to the ends of fully duplex DNA.

The 30-kDa C-terminal domain of the RecB protein is critical for the nuclease activity, but not the helicase activity, of the RecBCD enzyme from Escherichia coli

The RecBCD enzyme from Escherichia coli is an ATP-dependent helicase and an ATP-stimulated nuclease. The 3' --> 5' exonuclease activity on double-stranded DNA is suppressed when the enzyme encounters a recombinational hot spot, called chi (chi). We have prepared a RecB deletion mutant (RecB1-929) by using results of limited proteolysis experiments that indicated that the RecB subunit consists of two main domains. The RecB1-929 protein, comprising the 100-kDa N-terminal domain of RecB, is an ATP-dependent helicase and a single-stranded DNA-dependent ATPase. Reconstitution of RecB1-929 with RecC and RecD leads to processive unwinding of a linearized plasmid. However, the reconstituted RecB1-929CD enzyme has lost the single-strand endo- and exonuclease and the double-strand exonuclease activities of the RecBCD enzyme. These results show that the 30-kDa C-terminal domain of RecB has an important role in the nuclease activity of RecBCD. On the basis of these findings, we propose the RecB C-terminal domain swing model to explain RecBCD's transformation from a 3' --> 5' exonuclease to a helicase when it meets a chi site.

The RecD subunit of the RecBCD enzyme from Escherichia coli is a single-stranded DNA-dependent ATPase

We have expressed the RecD subunit of the RecBCD enzyme from Escherichia coli as a fusion protein with a 31-amino acid NH2-terminal extension including 6 consecutive histidine residues (HisRecD). The overexpressed fusion protein can be purified in urea-denatured form by metal chelate affinity chromatography. The mixture of renatured HisRecD protein and the RecB and RecC proteins has a high level of ATP-dependent nuclease activity with either single- or double-stranded DNA, enhanced DNA unwinding activity, enhanced ATP hydrolysis activity in the presence of a small DNA oligomer cosubstrate, and chi-cutting activity. These are all characteristics of the RecBCD holoenzyme. The HisRecD protein by itself hydrolyzes ATP in the presence of high concentrations of single-stranded DNA (polydeoxythymidine). The activity is unstable at 37 degrees C, but is measurable at room temperature (about 23 degrees C). The HisRecD has very little ATPase activity in the presence of a much shorter single-stranded DNA (oligodeoxy(thymidine)12). HisRecD hydrolyzes ATP more efficiently than GTP and UTP, and has very little activity with CTP. We also purified a fusion protein containing a Lys to Gln mutation in the putative ATP-binding site of RecD. This mutant protein has no ATPase activity, indicating that the observed ATP hydrolysis activity is intrinsic to the RecD protein itself.

A point mutation in Escherichia coli DNA helicase II renders the enzyme nonfunctional in two DNA repair pathways. Evidence for initiation of unwinding from a nick in vivo

Biosynthetic errors and DNA damage introduce mismatches and lesions in DNA that can lead to mutations. These abnormalities are susceptible to correction by a number of DNA repair mechanisms, each of which requires a distinct set of proteins. Escherichia coli DNA helicase II has been demonstrated to function in two DNA repair pathways, methyl-directed mismatch repair and UvrABC-mediated nucleotide excision repair. To define further the role of UvrD in DNA repair a site-specific mutant was characterized. The mutation, uvrDQ251E, resides within helicase motif III, a conserved segment of amino acid homology found in a superfamily of prokaryotic and eukaryotic DNA helicases. The UvrD-Q251E protein failed to complement the mutator and ultraviolet light-sensitive phenotypes of a uvrD deletion strain indicating that the mutant protein is inactive in both mismatch repair and excision repair. Biochemical characterization revealed a significant defect in the ability of the mutant enzyme to initiate unwinding at a nick. The elongation phase of the unwinding reaction was nearly normal. Together, the biochemical and genetic data provide evidence that UvrD-Q251E is dysfunctional because the mutant protein fails to initiate unwinding at the nick(s) used to initiate excision and subsequent repair synthesis. These results provide direct evidence to support the notion that helicase II initiates unwinding from a nick in vivo in mismatch repair and excision repair.

Monomeric RecBCD enzyme binds and unwinds DNA

RecBCD enzyme is a multifunctional nuclease that is essential for the major pathway of homologous genetic recombination in Escherichia coli. It has a potent helicase activity that uses ATP hydrolysis to unwind very long stretches of DNA. The functional form of RecBCD enzyme has been unclear, since M(r) of 250,000-655,000 have been previously reported. We have isolated two oligomeric forms of the enzyme, one (monomeric) containing a single copy of the RecB, RecC, and RecD polypeptides, and the other (dimeric) containing two copies of each polypeptide. We show here that the monomeric form of the enzyme (M(r) approximately 330,000) can form a stable initiation complex on the end of ds DNA. Depending on the nature of the ds end, KD estimates ranged from approximately 0.1 nM to approximately 0.7 nM in the presence of Mg2+ ions, which enhanced but was not required for binding. We further showed that the complex of monomeric RecBCD enzyme and a ds DNA end was competent to unwind DNA. A general model for the action of helicases has been proposed that uses repeated conformational changes between two states of a complex between DNA and a dimeric form of the enzyme. Our results make such a model unlikely for RecBCD enzyme.

Strand specificity of nicking of DNA at Chi sites by RecBCD enzyme. Modulation by ATP and magnesium levels

RecBCD enzyme is essential for the major pathway of homologous recombination of linear DNA in Escherichia coli. It is a potent nuclease and helicase and, during its unwinding of double-stranded DNA, makes single-strand scissions in the vicinity of Chi recombination hot spots. We report here that both the strand that is cut and the position of the cuts relative to Chi depended on the ATP to Mg2+ ratio. With ATP in excess, Chi-dependent nicks occurred, as we have previously reported, four to six nucleotides to the 3'-side of the Chi octamer (5'-GCTGGTGG-3') and were detected only on the strand bearing that sequence. Three differences were seen with Mg2+ in excess. 1) Chi-dependent 3'-ends were produced on the GCTGGTGG-containing strand closer to and within the Chi octamer. 2) Chi-dependent cuts occurred on the complementary DNA strand. 3) RecBCD enzyme destroyed the 3'-terminated strand of DNA from its entry point up to the vicinity of the Chi site, as others have previously reported. We show here that, with Mg2+ in excess, the enzyme continued to travel along DNA, after encountering a Chi site, releasing both strands of the DNA distal to Chi as single strands. We discuss potential biological consequences of these two modes of RecBCD enzyme-Chi interaction.

Unwinding of nucleosomal DNA by a DNA helicase

We have asked whether a DNA helicase can unwind DNA contained within both isolated native chromatin and reconstituted chromatin containing regularly spaced arrays of nucleosome cores on a linear tandem repeat sequence. We find that Escherichia coli recBCD enzyme is capable of unwinding these DNA substrates and displacing the nucleosomes, although both the rate and the processivity of enzymatic unwinding are inhibited (a maximum of 3- and > 25-fold, respectively) as the nucleosome density on the template is increased. The observed rate of unwinding is not affected if the histone octamer is chemically cross-linked; thus, dissociation, or splitting, of the histone octamer is not required for unwinding to occur. The unwinding of native chromatin isolated from HeLa cell nuclei occurs both in the absence and in the presence of linker histone H1. These results suggest that as helicases unwind DNA, they facilitate nuclear processes by acting to clear DNA of histones or DNA-binding proteins in general.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.

In vitro reconstitution of homologous recombination reactions

The proteins essential to homologous recombination in E. coli have been purified and their individual activities have been identified, permitting biochemical reconstitution of steps that comprise the cellular recombination process. This review focuses on the biochemical events responsible for the initiation and homologous pairing steps of genetic recombination. The properties of an in vitro recombination reaction that requires the concerted action of recA, recBCD, and SSB proteins and that is stimulated by the recombination hotspot, Chi(chi), are described. The recBCD enzyme serves as the initiator of this reaction; its DNA helicase activity produces single-stranded DNA that is used by the recA protein to promote homologous pairing and DNA strand invasion of supercoiled (recipient) DNA. The SSB protein acts to trap the single-stranded DNA produced by recBCD enzyme and to facilitate pairing by the recA protein. The chi regulatory sequence acts in cis by attenuating the nuclease, but not the helicase, activity of recBCD enzyme. This attenuation assures the preservation of ssDNA produced by the DNA helicase activity and is responsible for the simulation in vitro and, presumably, in vivo. The attenuation of nuclease activity by chi results in the loss or functional inactivation of the recD subunit.

In vivo studies on the interaction of RecBCD enzyme and lambda Gam protein

The interaction between the RecBCD enzyme of Escherichia coli and the lambda Gam protein was investigated. Two types of experiments were done. In one type, Gam protein was produced by transient induction of the cells lysogenic for lambda cI857gam+. The presence of Gam protein, which inhibits RecBCD nuclease, enabled these cells to support the growth of a gene 2 mutant of bacteriophage T4 (T4 2). The lysogens overproducing the RecB subunit of RecBCD enzyme could titrate Gam protein and thus prevent the growth of T4 2. In contrast, the lysogens overproducing either RecC or RecD retained their capacity for growth of T4 2. It is therefore concluded that the RecB subunit is capable of binding Gam protein. In the second type of experiments, Gam protein was provided by derepressing the gamS gene on the plasmid pSF117 (S. A. Friedman and J. B. Hays, Gene 43:255-263, 1986). The presence of this protein did not interfere with the growth of wild-type cells (which were F-). Gam protein had a certain effect on recF mutants, whose doubling time became significantly longer. This suggests that the recF gene product plays an important role in maintenance of viability of the Gam-expressing cells. Gam protein exerted the most striking effect on growth of Hfr bacteria. In its presence, Hfr bacteria grew extremely slowly, but their ability to transfer DNA to recipient cells was not affected. We showed that the effect on growth of Hfr resulted from the interaction between the RecBCD-Gam complex and the integrated F plasmid.

Molecular organization and nucleotide sequence of the recG locus of Escherichia coli K-12

The nucleotide sequence of the Escherichia coli K-12 recG gene was determined. recG was identified as an open reading frame located between the spoT operon and the convergent gltS gene. It encodes a polypeptide of 693 amino acids which was identified as a 76-kDa protein by sodium dodecyl sulfate-polyacrylamide gel electrophoresis after it was labeled with [35S]methionine in maxicells. The sequence determined revealed no obvious promoter. Synthesis of RecG by plasmids carrying the intact gene varied with the orientation of the insert relative to the vector promoter and with the extent of upstream spoT operon sequence included in the construction. It is concluded that recG is the fourth and last gene in the spoT operon, although a possible promoter for independent transcription of spoU and recG was identified near the end of the spoT gene. The primary sequence of RecG revealed that it is related to proteins that act as helicases and has a well-conserved motif identified with ATP binding.

Interaction of RecBCD enzyme with DNA damaged by gamma radiation

The DNA of a gene 2 mutant (T4 2-) of phage T4 is degraded by RecBCD enzyme in the bacterial cytoplasm. Under normal conditions, recBCD+ cells are therefore incapable of supporting the growth of phage T4 2-. Only if the nucleolytic activity of RecBCD enzyme is absent from the cytoplasm are T4 2(-)-infected bacteria able to form plaques. We found that recBCD+ cells can form plaques if, before infection with T4 2-, they have been exposed to gamma radiation. It is suggested that gamma ray-induced lesions of the bacterial DNA (e.g., double-strand breaks) bind RecBCD enzyme. This binding enables the enzyme to begin to degrade the bacterial chromosome, but simultaneously prevents its degradative action on the ends of minor DNA species, such as unprotected infecting phage chromosomes. Degradation of the chromosomal DNA, which occurs during the early postirradiation period, ceases about 60 min after gamma ray exposure. The reappearance of the nucleolytic action of RecBCD enzyme on T4 2- DNA accompanies the cessation of degradation of bacterial DNA. Both, this cessation and the reappearance of the nucleolytic action of ReCBCD enzyme on T4 2- DNA depend on a functional recA gene product. These results suggest that postirradiation DNA degradation is controlled by the recA-dependent removal of RecBCD enzyme from the damaged chromosome. By making use of the temperature-sensitive mutant recB270, we showed that RecBCD-mediated repair of gamma ray-induced lesions occurs during the early postirradiation period, i.e. during postirradiation DNA degradation. It is shown that the RecD subunit of RecBCD enzyme also participates in this repair.

Interaction of lambda Gam protein with the RecD subunit of RecBCD enzyme increases radioresistance of the wild-type Escherichia coli

By making use of the gam(+)-plasmid, the so-called gam-dependent radioresistance was studied. This resistance is the result of the interaction between Gam protein (encoded by the gam gene of lambda) and RecBCD enzyme of Escherichia coli. gam-dependent radioresistance is observed in recB+ recC+ recD+ but not in recB+ recC+ recD- cells. It is suggested that Gam protein interacts specifically with the RecD subunit of RecBCD enzyme; the RecBC complex probably retains its activity in the presence of this viral protein.

DNA helicases of Escherichia coli

A great deal has been learned in the last 15 years with regard to how helicase enzymes participate in DNA metabolism and how they interact with their DNA substrates. However, many questions remain unanswered. Of critical importance is an understanding of how NTP hydrolysis and hydrogen-bond disruption are coupled. Several models exist and are being tested; none has been proven. In addition, an understanding of how a helicase disrupts the hydrogen bonds holding duplex DNA together is lacking. Recently, helicase enzymes that unwind duplex RNA and DNA.RNA hybrids have been described. In some cases, these are old enzymes with new activities. In other cases, these are new enzymes only recently discovered. The significance of these reactions in the cell remains to be clarified. However, with the availability of significant amounts of these enzymes in a highly purified state, and mutant alleles in most of the genes encoding them, the answers to these questions should be forthcoming. The variety of helicases found in E. coli, and the myriad processes these enzymes are involved in, were perhaps unexpected. It seems likely that an equally large number of helicases will be discovered in eukaryotic cells. In fact, several helicases have been identified and purified from eukaryotic sources ranging from viruses to mouse cells (4-13, 227-234). Many of these helicases have been suggested to have roles in DNA replication, although this remains to be shown conclusively. Helicases with roles in DNA repair, recombination, and other aspects of DNA metabolism are likely to be forthcoming as we learn more about these processes in eukaryotic cells.

The single-stranded DNA-binding protein of Escherichia coli

The single-stranded DNA-binding protein (SSB) of Escherichia coli is involved in all aspects of DNA metabolism: replication, repair, and recombination. In solution, the protein exists as a homotetramer of 18,843-kilodalton subunits. As it binds tightly and cooperatively to single-stranded DNA, it has become a prototypic model protein for studying protein-nucleic acid interactions. The sequences of the gene and protein are known, and the functional domains of subunit interaction, DNA binding, and protein-protein interactions have been probed by structure-function analyses of various mutations. The ssb gene has three promoters, one of which is inducible because it lies only two nucleotides from the LexA-binding site of the adjacent uvrA gene. Induction of the SOS response, however, does not lead to significant increases in SSB levels. The binding protein has several functions in DNA replication, including enhancement of helix destabilization by DNA helicases, prevention of reannealing of the single strands and protection from nuclease digestion, organization and stabilization of replication origins, primosome assembly, priming specificity, enhancement of replication fidelity, enhancement of polymerase processivity, and promotion of polymerase binding to the template. E. coli SSB is required for methyl-directed mismatch repair, induction of the SOS response, and recombinational repair. During recombination, SSB interacts with the RecBCD enzyme to find Chi sites, promotes binding of RecA protein, and promotes strand uptake.

recB recC-dependent processing of heteroduplex DNA stimulates recombination of an adjacent gene in Escherichia coli

The effect of DNA mismatched repair on the genetic recombination of a gene adjacent to the mismatch site (MS) was tested by using four mismatch configurations. An MS was constructed in a well-characterized plasmid recombination substrate, and recombination with a resident compatible plasmid was measured after transformation of the mismatched plasmid into Escherichia coli. The mismatched plasmids were constructed such that one of the DNA strands was methylated by the DNA adenine methylase (Dam), while the other strand was unmethylated. The processing of a hemimethylated single-base-pair mismatch had no effect on the recombination of the adjacent gene, suggesting that the most efficient (Dam-instructed) mismatch repair process does not secondarily promote genetic recombination. However, mismatches that could form an ordered secondary structure resembling a cruciform increased the recombination of this adjacent gene at least 20-fold. An identical mismatch that could not form an ordered secondary structure had no effect in this system. The increased frequency of recombination observed was found to require the recB or recC gene product or both. Furthermore, the recombination appeared unidirectional, in that the cruciform-containing plasmid did not produce stable transformants. Our results support a model in which the cruciform-containing plasmid can participate in recombination with the resident plasmid but is unable to produce stable transformant progeny. A proposed role for the RecBCD enzyme (ExoV) in this process is discussed.

The recB gene product is essential for exonuclease V-dependent DNA degradation in vivo

The recB21 mutation abolishes the exonuclease activity of the RecBCD enzyme (exonuclease V) of Escherichia coli. This might be due to the polar effect of recB21 on expression of the recD gene, the product of which is an essential component of the RecBCD enzyme. To achieve synthesis of the recD gene product, the recD+ plasmid was introduced into the recB21 mutant. Degradation of the endogenous DNA damaged by gamma-rays and degradation of the DNA of a phage T4 gene 2 mutant were nevertheless abnormally small in this strain. Thus, the functional recB gene product is required for the degradative function of the RecBCD enzyme.

recB and recC genes of Salmonella typhimurium

We have investigated the genetic organization of the recB (exonuclease V) and recC (exonuclease V) genes of Salmonella typhimurium. A detailed genetic map is constructed that includes the relative order in the chromosome, P22 cotransduction frequencies, and the orientation of transcription of the recB and recC genes. In addition, the isolation and characterization of Mu dJ insertion mutations in recB and recC are discussed.

RecBC enzyme activity is required for far-UV induced respiration shutoff in Escherichia coli K12

Shutoff of respiration is one of a number of recA+ lexA+ dependent (SOS) responses caused by far ultraviolet (245 nm) radiation (UV) damage of DNA in Escherichia coli cells. Thus far no rec/lex response has been shown to require the recB recC gene product, the RecBC enzyme. We report in this paper that UV-induced respiration shutoff did not occur in either of these radiation-sensitive derivatives of K12 strain AB1157 nor in the recB recC double mutant. The sbcB gene product is exonuclease I and it has been reported that the triple mutant strain recB recC sbcB has near normal recombination efficiency and resistance to UV. The sbcB strain shut off its respiration after UV but the triple mutant did not show UV-induced respiration shutoff; the shutoff and death responses were uncoupled. We concluded that respiration shutoff requires RecBC enzyme activity. The RecBC enzyme has ATP-dependent double-strand exonuclease activity, helicase activity and several other activities. We tested a recBC+ (double dagger) mutant strain (recC 1010) that had normal recombination efficiency and resistance to UV but which possessed no ATP-dependent double-strand exonuclease activity. This strain did not shut off its respiration. The presence or absence of other RecBC enzyme activities in this mutant is not known. These results support the hypothesis that ATP-dependent double-strand exonuclease activity is necessary for UV-induced respiration shutoff.

Substrate specificity of the DNA unwinding activity of the RecBC enzyme of Escherichia coli

The RecBC enzyme of Escherichia coli promotes genetic recombination of phage or bacterial chromosomes. The purified enzyme travels through duplex DNA, unwinding and rewinding the DNA with the transient production of potentially recombinogenic single-stranded DNA. The studies reported here are aimed at understanding which chromosomal forms allow the entry of RecBC enzyme and hence may undergo RecBC enzyme-mediated recombination. Circular duplex molecules, whether covalently closed, nicked or containing single-stranded gaps of 10 to 774 nucleotides, are not detectably unwound by RecBC enzyme. Linear duplex molecules are readily unwound if they have a nearly flush-ended terminus whose 5' and 3' ends are offset by no more than about 25 nucleotides; molecules with longer single-stranded tails are poorly bound by RecBC enzyme and are infrequently unwound. The single-strand endonuclease activity of RecBC enzyme can slowly cleave gapped circles to produce molecules presumably capable of being unwound. These results provide an enzymatic basis for the recombinogenicity of double-stranded DNA ends established from genetic studies of RecBC enzyme and Chi sites, recognition sites for RecBC enzyme-mediated DNA strand cleavage.