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

Trans-complementation by the RecB nuclease domain of RecBCD enzyme reveals new insight into RecA loading upon χ recognition

The loading of RecA onto ssDNA by RecBCD is an essential step of RecBCD-mediated homologous recombination. RecBCD facilitates RecA-loading onto ssDNA in a χ-dependent manner via its RecB nuclease domain (RecBn). Before recognition of χ, RecBn is sequestered through interactions with RecBCD. It was proposed that upon χ-recognition, RecBn undocks, allowing RecBn to swing out via a contiguous 70 amino acid linker to reveal the RecA-loading surface, and then recruit and load RecA onto ssDNA. We tested this hypothesis by examining the interactions between RecBn (RecB928-1180) and truncated RecBCD (RecB1-927CD) lacking the nuclease domain. The reconstituted complex of RecB1-927CD and RecBn is functional in vitro and in vivo. Our results indicate that despite being covalently severed from RecB1-927CD, RecBn can still load RecA onto ssDNA, establishing that RecBn does not function while only remaining tethered to the RecBCD complex via the linker. Instead, RecBCD undergoes a χ-induced intramolecular rearrangement to reveal the RecA-loading surface.

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.

Processive DNA Unwinding by RecBCD Helicase in the Absence of Canonical Motor Translocation

Escherichia coli RecBCD is a DNA helicase/nuclease that functions in double-stranded DNA break repair. RecBCD possesses two motors (RecB, a 3' to 5' translocase, and RecD, a 5' to 3' translocase). Current DNA unwinding models propose that motor translocation is tightly coupled to base pair melting. However, some biochemical evidence suggests that DNA melting of multiple base pairs may occur separately from single-stranded DNA translocation. To test this hypothesis, we designed DNA substrates containing reverse backbone polarity linkages that prevent ssDNA translocation of the canonical RecB and RecD motors. Surprisingly, we find that RecBCD can processively unwind DNA for at least 80bp beyond the reverse polarity linkages. This ability requires an ATPase active RecB motor, the RecB "arm" domain, and also the RecB nuclease domain, but not its nuclease activity. These results indicate that RecBCD can unwind duplex DNA processively in the absence of ssDNA translocation by the canonical motors and that the nuclease domain regulates the helicase activity of RecBCD.

The DNA Exonucleases of Escherichia coli

DNA exonucleases, enzymes that hydrolyze phosphodiester bonds in DNA from a free end, play important cellular roles in DNA repair, genetic recombination and mutation avoidance in all organisms. This article reviews the structure, biochemistry, and biological functions of the 17 exonucleases currently identified in the bacterium Escherichia coli. These include the exonucleases associated with DNA polymerases I (polA), II (polB), and III (dnaQ/mutD); Exonucleases I (xonA/sbcB), III (xthA), IV, VII (xseAB), IX (xni/xgdG), and X (exoX); the RecBCD, RecJ, and RecE exonucleases; SbcCD endo/exonucleases; the DNA exonuclease activities of RNase T (rnt) and Endonuclease IV (nfo); and TatD. These enzymes are diverse in terms of substrate specificity and biochemical properties and have specialized biological roles. Most of these enzymes fall into structural families with characteristic sequence motifs, and members of many of these families can be found in all domains of life.

The nuclease activities of both the Smr domain and an additional LDLK motif are required for an efficient anti-recombination function of Helicobacter pylori MutS2

Helicobacter pylori, a human pathogen, is a naturally and constitutively competent bacteria, displaying a high rate of intergenomic recombination. While recombination events are essential for evolution and adaptation of H. pylori to dynamic gastric niches and new hosts, such events should be regulated tightly to maintain genomic integrity. Here, we analyze the role of the nuclease activity of MutS2, a protein that limits recombination during transformation in H. pylori. In previously studied MutS2 proteins, the C-terminal Smr domain was mapped as the region responsible for its nuclease activity. We report here that deletion of Smr domain does not completely abolish the nuclease activity of HpMutS2. Using bioinformatics analysis and mutagenesis, we identified an additional and novel nuclease motif (LDLK) at the N-terminus of HpMutS2 unique to Helicobacter and related ε-proteobacterial species. A single point mutation (D30A) in the LDLK motif and the deletion of Smr domain resulted in ∼ 5-10-fold loss of DNA cleavage ability of HpMutS2. Interestingly, the mutant forms of HpMutS2 wherein the LDLK motif was mutated or the Smr domain was deleted were unable to complement the hyper-recombination phenotype of a mutS2(-) strain, suggesting that both nuclease sites are indispensable for an efficient anti-recombinase activity of HpMutS2.

Superfamily I helicases as modular components of DNA-processing machines

Helicases are a ubiquitous and abundant group of motor proteins that couple NTP binding and hydrolysis to processive unwinding of nucleic acids. By targeting this activity to a wide range of specific substrates, and by coupling it with other catalytic functionality, helicases fulfil diverse roles in virtually all aspects of nucleic acid metabolism. The present review takes a look back at our efforts to elucidate the molecular mechanisms of UvrD-like DNA helicases. Using these well-studied enzymes as examples, we also discuss how helicases are programmed by interactions with partner proteins to participate in specific cellular functions.

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.

Intersubunit signaling in RecBCD enzyme, a complex protein machine regulated by Chi hot spots

The Escherichia coli RecBCD helicase-nuclease, a paradigm of complex protein machines, initiates homologous genetic recombination and the repair of broken DNA. Starting at a duplex end, RecBCD unwinds DNA with its fast RecD helicase and slower RecB helicase on complementary strands. Upon encountering a Chi hot spot (5'-GCTGGTGG-3'), the enzyme produces a new 3' single-strand end and loads RecA protein onto it, but how Chi regulates RecBCD is unknown. We report a new class of mutant RecBCD enzymes that cut DNA at novel positions that depend on the DNA substrate length and that are strictly correlated with the RecB:RecD helicase rates. We conclude that in the mutant enzymes when RecD reaches the DNA end, it signals RecB's nuclease domain to cut the DNA. As predicted by this interpretation, the mutant enzymes cut closer to the entry point on DNA when unwinding is blocked by another RecBCD molecule traveling in the opposite direction. Furthermore, when RecD is slowed by a mutation altering its ATPase site such that RecB reaches the DNA end before RecD does, the length-dependent cuts are abolished. These observations lead us to hypothesize that, in wild-type RecBCD enzyme, Chi is recognized by RecC, which then signals RecD to stop, which in turn signals RecB to cut the DNA and load RecA. We discuss support for this "signal cascade" hypothesis and tests of it. Intersubunit signaling may regulate other complex protein machines.

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.

The RecA Binding Locus of RecBCD Is a General Domain for Recruitment of DNA Strand Exchange Proteins

RecBCD enzyme facilitates loading of RecA protein onto ssDNA produced by its helicase/nuclease activity. This process is essential for RecBCD-mediated homologous recombination. Here, we establish that the C-terminal nuclease domain of the RecB subunit (RecBnuc) forms stable complexes with RecA. Interestingly, RecBnuc also interacts with and loads noncognate DNA strand exchange proteins. Interaction is with a conserved element of the RecA-fold, but because the binding to noncognate proteins decreases in a phylogenetically consistent way, species-specific interactions are also present. RecBnuc does not impede activities of RecA that are important to DNA strand exchange, consistent with its role in targeting of RecA. Modeling predicts the interaction interface for the RecA-RecBCD complex. Because a similar interface is involved in the binding of human Rad51 to the conserved BRC repeat of BRCA2 protein, the RecB-domain may be one of several structural domains that interact with and recruit DNA strand exchange proteins to DNA.

RecBCD enzyme is a bipolar DNA helicase

Escherichia coli RecBCD is a heterotrimeric helicase/nuclease that catalyses a complex reaction in which double-strand breaks in DNA are processed for repair by homologous recombination. For some time it has been clear that the RecB subunit possesses a 3' --> 5' DNA helicase activity, which was thought to drive DNA translocation and unwinding in the RecBCD holoenzyme. Here we show that purified RecD protein is also a DNA helicase, but one that possesses a 5' --> 3' polarity. We also show that the RecB and RecD helicases are both active in intact RecBCD, because the enzyme remains capable of processive DNA unwinding when either of these subunits is inactivated by mutation. These findings point to a bipolar translocation model for RecBCD in which the two DNA helicases are complementary, travelling with opposite polarities, but in the same direction, on each strand of the antiparallel DNA duplex. This bipolar motor organization helps to explain various biochemical properties of RecBCD, notably its exceptionally high speed and processivity, and offers a mechanistic insight into aspects of RecBCD function.

A DNA repair system specific for thermophilic Archaea and bacteria predicted by genomic context analysis

During a systematic analysis of conserved gene context in prokaryotic genomes, a previously undetected, complex, partially conserved neighborhood consisting of more than 20 genes was discovered in most Archaea (with the exception of Thermoplasma acidophilum and Halobacterium NRC-1) and some bacteria, including the hyperthermophiles Thermotoga maritima and Aquifex aeolicus. The gene composition and gene order in this neighborhood vary greatly between species, but all versions have a stable, conserved core that consists of five genes. One of the core genes encodes a predicted DNA helicase, often fused to a predicted HD-superfamily hydrolase, and another encodes a RecB family exonuclease; three core genes remain uncharacterized, but one of these might encode a nuclease of a new family. Two more genes that belong to this neighborhood and are present in most of the genomes in which the neighborhood was detected encode, respectively, a predicted HD-superfamily hydrolase (possibly a nuclease) of a distinct family and a predicted, novel DNA polymerase. Another characteristic feature of this neighborhood is the expansion of a superfamily of paralogous, uncharacterized proteins, which are encoded by at least 20-30% of the genes in the neighborhood. The functional features of the proteins encoded in this neighborhood suggest that they comprise a previously undetected DNA repair system, which, to our knowledge, is the first repair system largely specific for thermophiles to be identified. This hypothetical repair system might be functionally analogous to the bacterial-eukaryotic system of translesion, mutagenic repair whose central components are DNA polymerases of the UmuC-DinB-Rad30-Rev1 superfamily, which typically are missing in thermophiles.

Structure and function of the Escherichia coli RecE protein, a member of the RecB nuclease domain family

The RecB subunit of the Escherichia coli RecBCD enzyme has both helicase and nuclease activities. The helicase function was localized to an N-terminal domain, whereas the nuclease activity was found in a C-terminal domain. Recent analysis has uncovered a group of proteins that have weak amino acid sequence similarity to the RecB nuclease domain and that are proposed to constitute a family of related proteins (Aravind, L., Walker, D. R., and Koonin, E. V. (1999) Nucleic Acids Res. 27, 1223-1242). One is the E. coli RecE protein (exonuclease VIII), an ATP-independent exonuclease that degrades the 5'-terminated strand of double-stranded DNA. We have made mutations in several residues of RecE that align with the critical residues of RecB, and we find that the mutations reduce or abolish the nuclease activity of RecE but do not affect the enzyme binding to linear double-stranded DNA. Proteolysis experiments with subtilisin show that a stable 34-kilodalton C-terminal domain that contains these critical residues has nuclease activity, whereas no stable proteolytic fragments accumulate from the N-terminal portion of RecE. These results show that RecE has a nuclease domain and active site that are similar to RecB, despite the very weak sequence similarity between the two proteins. These similarities support the hypothesis that the nuclease domains of the two proteins are evolutionarily related.

Nuclease activity is essential for RecBCD recombination in Escherichia coli

RecBCD has two conflicting roles in Escherichia coli. (i) As ExoV, it is a potent double-stranded (ds)DNA exonuclease that destroys linear DNA produced by restriction of foreign DNA. (ii) As a recombinase, it promotes repair of dsDNA breaks and genetic recombination in the vicinity of chi recombination hot-spots. These paradoxical roles are accommodated by chi-dependent attenuation of RecBCD exonuclease activity and concomitant conversion of the enzyme to a recombinase. To challenge the proposal that chi converts RecBCD from a destructive exonuclease to a recombinogenic helicase, we mutated the nuclease catalytic centre of RecB and tested the resulting mutants for genetic recombination and DNA repair in vivo. We predicted that, if nuclease activity inhibits recombination and helicase activity is sufficient for recombination, the mutants would be constitutive recombinases, as has been seen in recD null mutants. Conversely, if nuclease activity is required, the mutants would be recombination deficient. Our results indicate that 5' --> 3' exonuclease activity is essential for recombination by RecBCD at chi recombination hot-spots and at dsDNA ends in recD mutants. In the absence of RecB-dependent nuclease function, recombination becomes entirely dependent on the 5' --> 3' single-stranded (ss)DNA exonuclease activity of RecJ and the helicase activity of RecBC(D).

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.