Unwinding of nucleosomal DNA by a DNA helicase

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.

Host nucleases generate prespacers for primed adaptation in the E. coli type I-E CRISPR-Cas system

CRISPR-Cas systems provide prokaryotes with adaptive immunity against foreign nucleic acids. In Escherichia coli, immunity is acquired upon integration of 33-bp spacers into CRISPR arrays. DNA targets complementary to spacers get degraded and serve as a source of new spacers during a process called primed adaptation. Precursors of such spacers, prespacers, are ~33-bp double-stranded DNA fragments with a ~4-nt 3' overhang. The mechanism of prespacer generation is not clear. Here, we use FragSeq and biochemical approaches to determine enzymes involved in generation of defined prespacer ends. We demonstrate that RecJ is the main exonuclease trimming 5' ends of prespacer precursors, although its activity can be partially substituted by ExoVII. The RecBCD complex allows single strand-specific RecJ to process double-stranded regions flanking prespacers. Our results reveal intricate functional interactions of genome maintenance proteins with CRISPR interference and adaptation machineries during generation of prespacers capable of integration into CRISPR arrays.

Insight into the biochemical mechanism of DNA helicases provided by bulk-phase and single-molecule assays

There are multiple assays available that can provide insight into the biochemical mechanism of DNA helicases. For the first 22 years since their discovery, bulk-phase assays were used. These include gel-based, spectrophotometric, and spectrofluorometric assays that revealed many facets of these enzymes. From 2001, single-molecule studies have contributed additional insight into these DNA nanomachines to reveal details on energy coupling, step size, processivity as well as unique aspects of individual enzyme behavior that were masked in the averaging inherent in ensemble studies. In this review, important aspects of the study of helicases are discussed including beginning with active, nuclease-free enzyme, followed by several bulk-phase approaches that have been developed and still find widespread use today. Finally, two single-molecule approaches are discussed, and the resulting findings are related to the results obtained in bulk-phase studies.

Single-molecule studies of helicases and translocases in prokaryotic genome-maintenance pathways

Helicases involved in genomic maintenance are a class of nucleic-acid dependent ATPases that convert the energy of ATP hydrolysis into physical work to execute irreversible steps in DNA replication, repair, and recombination. Prokaryotic helicases provide simple models to understand broadly conserved molecular mechanisms involved in manipulating nucleic acids during genome maintenance. Our understanding of the catalytic properties, mechanisms of regulation, and roles of prokaryotic helicases in DNA metabolism has been assembled through a combination of genetic, biochemical, and structural methods, further refined by single-molecule approaches. Together, these investigations have constructed a framework for understanding the mechanisms that maintain genomic integrity in cells. This review discusses recent single-molecule insights into molecular mechanisms of prokaryotic helicases and translocases.

Sequential eviction of crowded nucleoprotein complexes by the exonuclease RecBCD molecular motor

In physiological settings, all nucleic acids motor proteins must travel along substrates that are crowded with other proteins. However, the physical basis for how motor proteins behave in these highly crowded environments remains unknown. Here, we use real-time single-molecule imaging to determine how the ATP-dependent translocase RecBCD travels along DNA occupied by tandem arrays of high-affinity DNA binding proteins. We show that RecBCD forces each protein into its nearest adjacent neighbor, causing rapid disruption of the protein-nucleic acid interaction. This mechanism is not the same way that RecBCD disrupts isolated nucleoprotein complexes on otherwise naked DNA. Instead, molecular crowding itself completely alters the mechanism by which RecBCD removes tightly bound protein obstacles from DNA.

DNA looping mediates nucleosome transfer

Proper cell function requires preservation of the spatial organization of chromatin modifications. Maintenance of this epigenetic landscape necessitates the transfer of parental nucleosomes to newly replicated DNA, a process that is stringently regulated and intrinsically linked to replication fork dynamics. This creates a formidable setting from which to isolate the central mechanism of transfer. Here we utilized a minimal experimental system to track the fate of a single nucleosome following its displacement, and examined whether DNA mechanics itself, in the absence of any chaperones or assembly factors, may serve as a platform for the transfer process. We found that the nucleosome is passively transferred to available dsDNA as predicted by a simple physical model of DNA loop formation. These results demonstrate a fundamental role for DNA mechanics in mediating nucleosome transfer and preserving epigenetic integrity during replication.

Mechanics and Single-Molecule Interrogation of DNA Recombination

The repair of DNA by homologous recombination is an essential, efficient, and high-fidelity process that mends DNA lesions formed during cellular metabolism; these lesions include double-stranded DNA breaks, daughter-strand gaps, and DNA cross-links. Genetic defects in the homologous recombination pathway undermine genomic integrity and cause the accumulation of gross chromosomal abnormalities-including rearrangements, deletions, and aneuploidy-that contribute to cancer formation. Recombination proceeds through the formation of joint DNA molecules-homologously paired but metastable DNA intermediates that are processed by several alternative subpathways-making recombination a versatile and robust mechanism to repair damaged chromosomes. Modern biophysical methods make it possible to visualize, probe, and manipulate the individual molecules participating in the intermediate steps of recombination, revealing new details about the mechanics of genetic recombination. We review and discuss the individual stages of homologous recombination, focusing on common pathways in bacteria, yeast, and humans, and place particular emphasis on the molecular mechanisms illuminated by single-molecule methods.

Chemo-mechanical pushing of proteins along single-stranded DNA

Single-stranded (ss)DNA binding (SSB) proteins bind with high affinity to ssDNA generated during DNA replication, recombination, and repair; however, these SSBs must eventually be displaced from or reorganized along the ssDNA. One potential mechanism for reorganization is for an ssDNA translocase (ATP-dependent motor) to push the SSB along ssDNA. Here we use single molecule total internal reflection fluorescence microscopy to detect such pushing events. When Cy5-labeled Escherichia coli (Ec) SSB is bound to surface-immobilized 3'-Cy3-labeled ssDNA, a fluctuating FRET signal is observed, consistent with random diffusion of SSB along the ssDNA. Addition of Saccharomyces cerevisiae Pif1, a 5' to 3' ssDNA translocase, results in the appearance of isolated, irregularly spaced saw-tooth FRET spikes only in the presence of ATP. These FRET spikes result from translocase-induced directional (5' to 3') pushing of the SSB toward the 3' ssDNA end, followed by displacement of the SSB from the DNA end. Similar ATP-dependent pushing events, but in the opposite (3' to 5') direction, are observed with EcRep and EcUvrD (both 3' to 5' ssDNA translocases). Simulations indicate that these events reflect active pushing by the translocase. The ability of translocases to chemo-mechanically push heterologous SSB proteins along ssDNA provides a potential mechanism for reorganization and clearance of tightly bound SSBs from ssDNA.

Nucleosome dynamics regulates DNA processing

The repair of DNA double strand breaks (DSBs) is critical for the maintenance of genome integrity. The first step in DSB repair by homologous recombination is processing of the ends by one of two resection pathways, exemplified by Saccharomyces cerevisiae Exo1 and Sgs1–Dna2. Here we report in vitro and in vivo studies that characterize the impact of chromatin on each resection pathway. We find that efficient resection by the Sgs1-Dna2 -dependent machinery requires a nucleosome-free gap adjacent to the DSB. Resection by Exo1 is blocked by nucleosomes, and processing activity can be partially restored by removal of the H2A-H2B dimers. Our study also supports a role for the dynamic incorporation of the H2A.Z histone variant in Exo1 processing, and it further suggests that the two resection pathways require distinct chromatin remodeling events in order to navigate chromatin structure.

Molecular traffic jams on DNA

All aspects of DNA metabolism-including transcription, replication, and repair-involve motor enzymes that move along genomic DNA. These processes must all take place on chromosomes that are occupied by a large number of other proteins. However, very little is known regarding how nucleic acid motor proteins move along the crowded DNA substrates that are likely to exist in physiological settings. This review summarizes recent progress in understanding how DNA-binding motor proteins respond to the presence of other proteins that lie in their paths. We highlight recent single-molecule biophysical experiments aimed at addressing this question, with an emphasis placed on analyzing the single-molecule, ensemble biochemical, and in vivo data from a mechanistic perspective.

PcrA-mediated disruption of RecA nucleoprotein filaments--essential role of the ATPase activity of RecA

The essential DNA helicase, PcrA, regulates recombination by displacing the recombinase RecA from the DNA. The nucleotide-bound state of RecA determines the stability of its nucleoprotein filaments. Using single-molecule fluorescence approaches, we demonstrate that RecA displacement by a translocating PcrA requires the ATPase activity of the recombinase. We also show that in a ‘head-on collision’ between a polymerizing RecA filament and a translocating PcrA, the RecA K72R ATPase mutant, but not wild-type RecA, arrests helicase translocation. Our findings demonstrate that translocation of PcrA is not sufficient to displace RecA from the DNA and assigns an essential role for the ATPase activity of RecA in helicase-mediated disruption of its filaments.

Single-molecule imaging reveals mechanisms of protein disruption by a DNA translocase

In physiological settings, nucleic-acid translocases must act on substrates occupied by other proteins, and an increasingly appreciated role of translocases is to catalyse protein displacement from RNA and DNA. However, little is known regarding the inevitable collisions that must occur, and the fate of protein obstacles and the mechanisms by which they are evicted from DNA remain unexplored. Here we sought to establish the mechanistic basis for protein displacement from DNA using RecBCD as a model system. Using nanofabricated curtains of DNA and multicolour single-molecule microscopy, we visualized collisions between a model translocase and different DNA-bound proteins in real time. We show that the DNA translocase RecBCD can disrupt core RNA polymerase, holoenzymes, stalled elongation complexes and transcribing RNA polymerases in either head-to-head or head-to-tail orientations, as well as EcoRI(E111Q), lac repressor and even nucleosomes. RecBCD did not pause during collisions and often pushed proteins thousands of base pairs before evicting them from DNA. We conclude that RecBCD overwhelms obstacles through direct transduction of chemomechanical force with no need for specific protein-protein interactions, and that proteins can be removed from DNA through active disruption mechanisms that act on a transition state intermediate as they are pushed from one nonspecific site to the next.

Investigation of translocation, DNA unwinding, and protein displacement by NS3h, the helicase domain from the hepatitis C virus helicase

Helicases are motor proteins that are involved in DNA and RNA metabolism, replication, recombination, transcription, and repair. The motors are powered by ATP binding and hydrolysis. Hepatitis C virus encodes a helicase called nonstructural protein (NS3). NS3 possesses protease and helicase activities on its N-terminal and C-terminal domains, respectively. The helicase domain of NS3 is termed NS3h. In vitro, NS3h catalyzes RNA and DNA unwinding in a 3'-5' direction. The directionality of unwinding is thought to arise in part from the enzyme's ability to translocate along DNA, but translocation has not been shown explicitly. We examined the DNA translocase activity of NS3h by using single-stranded oligonucleotide substrates containing a fluorescent probe on the 5' end. NS3h can bind to the ssDNA and in the presence of ATP move toward the 5' end. When the enzyme encounters the fluorescent probe, a fluorescence change is observed that allows translocation to be characterized. Under conditions that favor binding of one NS3h per DNA substrate (100 nM NS3h and 200 nM oligonucleotide), we find that NS3h translocates on ssDNA at a rate of 46 +/- 5 nucleotides/s, and that it can move for 230 +/- 60 nucleotides before dissociating from the DNA. The translocase activity of some helicases is responsible for displacing proteins that are bound to DNA. We studied protein displacement by using a ssDNA oligonucleotide covalently linked to biotin on the 5' end. Upon addition of streptavidin, a "protein block" was placed in the pathway of the helicase. Interestingly, NS3h was unable to displace streptavidin from the end of the oligonucleotide, despite its ability to translocate along the DNA. The DNA unwinding activity of NS3h was examined using a 22 bp duplex DNA substrate under conditions that were identical to those used to study translocation. NS3h exhibited little or no DNA unwinding under single-cycle conditions, supporting the conclusion that NS3h is a relatively poor helicase in its monomeric form, as has been reported. In summary, NS3h translocates on ssDNA as a monomer, but the translocase activity does not correspond to comparable DNA unwinding activity or protein displacement activity under identical conditions.

Does BLM helicase unwind nucleosomal DNA?

RecQ helicases maintain chromosome stability by resolving several highly specific DNA structures. BLM, the protein mutated in Bloom's syndrome, is a member of the RecQ helicase family, and possesses both DNA-unwinding and strand-annealing activity. In this study, we have investigated the unwinding activity of BLM on nucleosomal DNA, the natural nuclear substrate for the enzyme. We generated a DNA template including a strong nucleosome-positioning sequence flanked by forked DNA, which is reportedly one of the preferred DNA substrates for BLM. BLM did not possess detectable unwinding activity toward the forked DNA substrate. However, the truncated BLM, lacking annealing activity, unwound it partially. In the presence of the single-stranded DNA-binding protein RPA, the unwinding activity of both the full-length and the truncated BLMs was promoted. Next, the histone octamer was reconstituted onto the forked DNA to generate a forked mononucleosome. Full-length BLM did not unwind the nucleosomal DNA, but truncated BLM unwound it partially. The unwinding activity for the mononucleosome was not promoted dramatically with RPA. These results indicate that full-length BLM may require additional factors to unwind nucleosomal DNA in vivo, and that RPA is, on its own, unable to perform this auxiliary function.

Protein displacement by helicases

Helicases are ubiquitous enzymes that are vital to all living organisms. They are motor proteins that move in a specific direction along the nucleic acid and unwind the nucleic acid (DNA and RNA). ATP hydrolysis provides energy for helicase translocation and unwinding. The unwinding process provides ssDNA intermediates necessary for replication, recombination, and repair. Mutations in specific DNA helicases can lead to disruption in DNA metabolism. For example, mutations in helicases genes resulted in diseases such as xeroderma pigmentosum, cockayne's syndrome, Bloom's syndrome, and Werner's syndrome. During unwinding, helicases are most likely to encounter proteins while moving along the nucleic acid. Several different research groups have demonstrated that helicases shift or displace proteins from one nucleic acid-bound location to another. These protein-protein collisions could result in displacement of proteins from nucleic acid or dissociation of helicase from nucleic acid. This report describes several different methods developed to study protein displacement by DNA and RNA helicases.

Rad51 polymerization reveals a new chromatin remodeling mechanism

Rad51 protein is a well known protagonist of homologous recombination in eukaryotic cells. Rad51 polymerization on single-stranded DNA and its role in presynaptic filament formation have been extensively documented. Rad51 polymerizes also on double-stranded DNA but the significance of this filament formation remains unclear. We explored the behavior of Saccharomyces cerevisiae Rad51 on dsDNA and the influence of nucleosomes on Rad51 polymerization mechanism to investigate its putative role in chromatin accessibility to recombination machinery. We combined biochemical approaches, transmission electron microscopy (TEM) and atomic force microscopy (AFM) for analysis of the effects of the Rad51 filament on chromatinized templates. Quantitative analyses clearly demonstrated the occurrence of chromatin remodeling during nucleoprotein filament formation. During Rad51 polymerization, recombinase proteins moved all the nucleosomal arrays in front of the progressing filament. This polymerization process had a powerful remodeling effect, as Rad51 destabilized the nucleosomes along considerable stretches of DNA. Similar behavior was observed with RecA. Thus, recombinase polymerization is a powerful mechanism of chromatin remodeling. These remarkable features open up new possibilities for understanding DNA recombination and reveal new types of ATP-dependent chromatin dynamics.

Influence of DNA end structure on the mechanism of initiation of DNA unwinding by the Escherichia coli RecBCD and RecBC helicases

Escherichia coli RecBCD is a bipolar DNA helicase possessing two motor subunits (RecB, a 3'-to-5' translocase, and RecD, a 5'-to-3' translocase) that is involved in the major pathway of recombinational repair. Previous studies indicated that the minimal kinetic mechanism needed to describe the ATP-dependent unwinding of blunt-ended DNA by RecBCD in vitro is a sequential n-step mechanism with two to three additional kinetic steps prior to initiating DNA unwinding. Since RecBCD can "melt out" approximately 6 bp upon binding to the end of a blunt-ended DNA duplex in a Mg(2+)-dependent but ATP-independent reaction, we investigated the effects of noncomplementary single-stranded (ss) DNA tails [3'-(dT)(6) and 5'-(dT)(6) or 5'-(dT)(10)] on the mechanism of RecBCD and RecBC unwinding of duplex DNA using rapid kinetic methods. As with blunt-ended DNA, RecBCD unwinding of DNA possessing 3'-(dT)(6) and 5'-(dT)(6) noncomplementary ssDNA tails is well described by a sequential n-step mechanism with the same unwinding rate (mk(U)=774+/-16 bp s(-1)) and kinetic step size (m=3.3+/-1.3 bp), yet two to three additional kinetic steps are still required prior to initiation of DNA unwinding (k(C)=45+/-2 s(-1)). However, when the noncomplementary 5' ssDNA tail is extended to 10 nt [5'-(dT)(10) and 3'-(dT)(6)], the DNA end structure for which RecBCD displays optimal binding affinity, the additional kinetic steps are no longer needed, although a slightly slower unwinding rate (mk(U)=538+/-24 bp s(-1)) is observed with a similar kinetic step size (m=3.9+/-0.5 bp). The RecBC DNA helicase (without the RecD subunit) does not initiate unwinding efficiently from a blunt DNA end. However, RecBC does initiate well from a DNA end possessing noncomplementary twin 5'-(dT)(6) and 3'-(dT)(6) tails, and unwinding can be described by a simple uniform n-step sequential scheme, without the need for the additional k(C) initiation steps, with a similar kinetic step size (m=4.4+/-1.7 bp) and unwinding rate (mk(obs)=396+/-15 bp s(-1)). These results suggest that the additional kinetic steps with rate constant k(C) required for RecBCD to initiate unwinding of blunt-ended and twin (dT)(6)-tailed DNA reflect processes needed to engage the RecD motor with the 5' ssDNA.

Kinetic control of Mg2+-dependent melting of duplex DNA ends by Escherichia coli RecBC

Escherichia coli RecBCD is a highly processive DNA helicase involved in double-strand break repair and recombination that possesses two helicase/translocase subunits with opposite translocation directionality (RecB (3' to 5') and RecD (5' to 3')). RecBCD has been shown to melt out approximately 5-6 bp upon binding to a blunt-ended duplex DNA in a Mg(2+)-dependent, but ATP-independent reaction. Here, we examine the binding of E. coli RecBC helicase (minus RecD), also a processive helicase, to duplex DNA ends in the presence and in the absence of Mg(2+) in order to determine if RecBC can also melt a duplex DNA end in the absence of ATP. Equilibrium binding of RecBC to DNA substrates with ends possessing pre-formed 3' and/or 5' single-stranded (ss)-(dT)(n) flanking regions (tails) (n ranging from zero to 20 nt) was examined by competition with a fluorescently labeled reference DNA and by isothermal titration calorimetry. The presence of Mg(2+) enhances the affinity of RecBC for DNA ends possessing 3' or 5'-(dT)(n) ssDNA tails with n<6 nt, with the relative enhancement decreasing as n increases from zero to six nt. No effect of Mg(2+) was observed for either the binding constant or the enthalpy of binding (Delta H(obs)) for RecBC binding to DNA with ssDNA tail lengths, n>or=6 nucleotides. Upon RecBC binding to a blunt duplex DNA end in the presence of Mg(2+), at least 4 bp at the duplex end become accessible to KMnO(4) attack, consistent with melting of the duplex end. Since Mg(2+) has no effect on the affinity or binding enthalpy of RecBC for a DNA end that is fully pre-melted, this suggests that the role of Mg(2+) is to overcome a kinetic barrier to melting of the DNA by RecBC and presumably also by RecBCD. These data also provide an accurate estimate (Delta H(obs)=8+/-1 kcal/mol) for the average enthalpy change associated with the melting of a DNA base-pair by RecBC.

Functionally distinct nucleosome-free regions in yeast require Rad7 and Rad16 for nucleotide excision repair

In yeast, Rad7 and Rad16 are two proteins required for nucleotide excision repair (NER) of non-transcribed chromatin. They have roles in damage recognition, in the postincision steps of NER, and in ultraviolet-light-dependent histone H3 acetylation. Moreover, Rad16 is an ATP-ase of the SNF2 superfamily and therefore might facilitate chromatin repair by nucleosome remodelling. Here, we used yeast rad7 Delta rad16 Delta mutants and show that Rad7-Rad16 is also required for NER of UV-lesions in three functionally distinct nucleosome-free regions (NFRs), the promoter and 3'-end of the URA3 gene and the ARS1 origin of replication. Moreover, rapid repair of UV-lesions by photolyase confirmed that nucleosomes were absent and that neither UV-damage formation nor rad7 Delta rad16 Delta mutations altered chromatin accessibility in NFRs. The data are consistent with a role of Rad7-Rad16 in damage recognition and processing in absence of nucleosomes. An additional role in nucleosome remodelling is discussed.

A nonuniform stepping mechanism for E. coli UvrD monomer translocation along single-stranded DNA

E. coli UvrD is an SF1 helicase involved in several DNA metabolic processes. Although a UvrD dimer is needed for helicase activity, a monomer can translocate with 3' to 5' directionality along single-stranded DNA, and this ATP-dependent translocation is likely involved in RecA displacement. In order to understand how the monomeric translocase functions, we have combined fluorescence stopped-flow kinetic methods with recently developed analysis methods to determine the kinetic mechanism, including ATP coupling stoichiometry, for UvrD monomer translocation along ssDNA. Our results suggest that the macroscopic rate of UvrD monomer translocation is not limited by each ATPase cycle but rather by a slow step (pause) in each translocation cycle that occurs after four to five rapid 1 nt translocation steps, with each rapid step coupled to hydrolysis of one ATP. These results suggest a nonuniform stepping mechanism that differs from either a Brownian motor or previous structure-based inchworm mechanisms.

Archaeal minichromosome maintenance (MCM) helicase can unwind DNA bound by archaeal histones and transcription factors

Protein-DNA complexes must be disassembled to facilitate DNA replication. Replication forks contain a helicase that unwinds the duplex DNA at the front of the fork. The minichromosome maintenance helicase from the archaeon Methanothermobacter thermautotrophicus required only ATP to unwind DNA bound into complexes by the M. thermautotrophicus archaeal histone HMtA2, transcription repressor TrpY, or into a transcription pre-initiation complex by M. thermautotrophicus TATA-box-binding protein, transcription factor B, and RNA polymerase. In contrast, the minichromosome maintenance helicase was unable to unwind DNA bound by this archaeal RNA polymerase in a stalled transcript-elongating complex.

Bipolar DNA Translocation Contributes to Highly Processive DNA Unwinding by RecBCD Enzyme

We recently demonstrated that the RecBCD enzyme is a bipolar DNA helicase that employs two single-stranded DNA motors of opposite polarity to drive translocation and unwinding of duplex DNA. We hypothesized that this organization may explain the exceptionally high rate and processivity of DNA unwinding catalyzed by the RecBCD enzyme. Using a stopped-flow dye displacement assay for unwinding activity, we test this idea by analyzing mutant RecBCD enzymes in which either of the two helicase motors is inactivated by mutagenesis. Like the wild-type RecBCD enzyme, the two mutant proteins maintain the ability to bind tightly to blunt duplex DNA ends in the absence of ATP. However, the rate of forward translocation for the RecB motor-defective enzyme is only approximately 30% of the wild-type rate, whereas for the RecD motor-defective enzyme, it is approximately 50%. More significantly, the processivity of translocation is substantially reduced by approximately 25- and 6-fold for each mutant enzyme, respectively. Despite retaining the capacity to bind blunt dsDNA, the RecB-mutant enzyme has lost the ability to unwind DNA unless the substrate contains a short 5'-terminated single-stranded DNA overhang. The consequences of this observation for the architecture of the single-stranded DNA motors in the initiation complex are discussed.

Forced Unraveling of Nucleosomes Assembled on Heterogeneous DNA Using Core Histones, NAP-1, and ACF

Periodic arrays of nucleosomes were assembled on heterogeneous DNA using core histones, the histone chaperone NAP-1, and ATP-dependent chromatin assembly and remodeling factor (ACF). The mechanical properties of these complexes were interrogated by stretching them with optical tweezers. Abrupt events releasing approximately 55-95 base-pairs of DNA, attributable to the non-equilibrium unraveling of individual nucleosomes, were frequently observed. This finding is comparable with a previous observation of 72-80 bp unraveling events for nucleosomes assembled by salt dialysis on a repeating sea urchin 5 S RNA positioning element, but the unraveling force varied over a wider range ( approximately 5-65 pN, with the majority of events at lower force). Because ACF assembles nucleosomes uniformly on heterogeneous DNA sequences, as in native chromatin, we attribute this variation to a dependence of the unraveling force on the DNA sequence within individual nucleosomes. The mean force increased from 24 pN to 31 pN as NaCl was decreased from 100 mM to 5 mM. Spontaneous DNA re-wrapping events were occasionally observed in real time during force relaxation. The observed wide variations in the dynamic force needed to unravel individual nucleosomes and the occurrences of sudden DNA re-wrapping events may have an important regulatory influence on DNA-directed nuclear processes, such as the binding of transcription factors and the movement of polymerase complexes on chromatin.

Translocation by the RecB motor is an absolute requirement for {chi}-recognition and RecA protein loading by RecBCD enzyme

RecBCD enzyme is a heterotrimeric helicase/nuclease that initiates homologous recombination at double-stranded DNA breaks. The enzyme is driven by two motor subunits, RecB and RecD, translocating on opposite single-strands of the DNA duplex. Here we provide evidence that, although both motor subunits can support the translocation activity for the enzyme, the activity of the RecB subunit is necessary for proper function of the enzyme both in vivo and in vitro. We demonstrate that the RecBCD(K177Q) enzyme, in which RecD helicase is disabled by mutation of the ATPase active site, complements recBCD deletion in vivo and displays all of the enzymatic activities that are characteristic of the wild-type enzyme in vitro. These include helicase and nuclease activities and the abilities to recognize the recombination hotspot chi and to coordinate the loading of RecA protein onto the ssDNA it produces. In contrast, the RecB(K29Q)CD enzyme, carrying a mutation in the ATPase site of RecB helicase, fails to complement recBCD deletion in vivo. We further show that even though RecB(K29Q)CD enzyme displays helicase and nuclease activities, its inability to translocate along the 3'-terminated strand results in the failure to recognize chi and to load RecA protein. Our findings argue that translocation by the RecB motor is required to deliver RecC subunit to chi, whereas the RecD subunit has a dispensable motor activity but an indispensable regulatory function.

Twin DNA pumps of a hexameric helicase provide power to simultaneously melt two duplexes

DnaB is the primary replicative helicase in Escherichia coli. We show here that DnaB can unwind two duplex arms simultaneously for an extended distance provided that two protein rings are positioned on opposite sides of the duplex arms. A putative eukaryotic replication fork helicase, Mcm4,6,7, performs a similar activity. Double-ringed melting of duplexes may function at a replication fork in vivo. This mechanism may apply to RuvB, since the proteins share mechanistic similarities. Thus, two RuvB hexamers may function in coordination at a Holliday junction to overcome regions of DNA heterology and DNA lesions. Furthermore, DnaB can actively translocate along DNA while encircling three DNA strands. Therefore, if DnaB encounters a D loop during fork progression, it will encircle the invading strand and may convert the recombinative invading strand to a daughter lagging strand. Finally, we present evidence that the DNA binding site of DnaB is buried inside its central channel.

Protein displacement by an assembly of helicase molecules aligned along single-stranded DNA

Helicases are molecular motors that unwind double-stranded DNA or RNA. In addition to unwinding nucleic acids, an important function of these enzymes seems to be the disruption of protein-nucleic acid interactions. Bacteriophage T4 Dda helicase can displace proteins bound to DNA, including streptavidin bound to biotinylated oligonucleotides. We investigated the mechanism of streptavidin displacement by varying the length of the oligonucleotide substrate. We found that a monomeric form of Dda catalyzed streptavidin displacement; however, the activity increased when multiple helicase molecules bound to the biotinylated oligonucleotide. The activity does not result from cooperative binding of Dda to the oligonucleotide. Rather, the increase in activity is a consequence of the directional bias in translocation of individual helicase monomers. Such a bias leads to protein-protein interactions when the lead monomer stalls owing to the presence of the streptavidin block.

DnaB drives DNA branch migration and dislodges proteins while encircling two DNA strands

DnaB is a ring-shaped, hexameric helicase that unwinds the E. coli DNA replication fork while encircling one DNA strand. This report demonstrates that DnaB can also encircle both DNA strands and then actively translocate along the duplex. With two strands positioned inside its central channel, DnaB translocates with sufficient force to displace proteins tightly bound to DNA with no resultant DNA unwinding. Thus, DnaB may clear proteins from chromosomal DNA. Furthermore, while encircling two DNA strands, DnaB can drive branch migration of a synthetic Holliday junction with heterologous duplex arms, suggesting that DnaB may be directly involved in DNA recombination in vivo. DnaB binds to just one DNA strand during branch migration. T7 phage gp4 protein also drives DNA branch migration, suggesting this activity generalizes to other ring-shaped helicases.

Dynamics of ATP-dependent chromatin assembly by ACF

The assembly of DNA into chromatin is a critical step in the replication and repair of the eukaryotic genome. It has been known for nearly 20 years that chromatin assembly is an ATP-dependent process. ATP-dependent chromatin-assembly factor (ACF) uses the energy of ATP hydrolysis for the deposition of histones into periodic nucleosome arrays, and the ISWI subunit of ACF is an ATPase that is related to helicases. Here we show that ACF becomes committed to the DNA template upon initiation of chromatin assembly. We also observed that ACF assembles nucleosomes in localized arrays, rather than randomly distributing them. By using a purified ACF-dependent system for chromatin assembly, we found that ACF hydrolyses about 2#150;4 molecules of ATP per base pair in the assembly of nucleosomes. This level of ATP hydrolysis is similar to that used by DNA helicases for the unwinding of DNA. These results suggest that a tracking mechanism exists in which ACF assembles chromatin as an ATP-driven DNA-translocating motor. Moreover, this proposed mechanism for ACF may be relevant to the function of other chromatin-remodelling factors that contain ISWI subunits.

Mechanical disruption of individual nucleosomes reveals a reversible multistage release of DNA

The dynamic structure of individual nucleosomes was examined by stretching nucleosomal arrays with a feedback-enhanced optical trap. Forced disassembly of each nucleosome occurred in three stages. Analysis of the data using a simple worm-like chain model yields 76 bp of DNA released from the histone core at low stretching force. Subsequently, 80 bp are released at higher forces in two stages: full extension of DNA with histones bound, followed by detachment of histones. When arrays were relaxed before the dissociated state was reached, nucleosomes were able to reassemble and to repeat the disassembly process. The kinetic parameters for nucleosome disassembly also have been determined.

Molecular cloning of a cDNA encoding mouse DNA helicase B, which has homology to Escherichia coli RecD protein, and identification of a mutation in the DNA helicase B from tsFT848 temperature-sensitive DNA replication mutant cells

DNA helicase B is a major DNA helicase in mouse FM3A cells. A temperature-sensitive mutant defective in DNA replication, tsFT848, isolated from FM3A cells, has a heat-labile DNA helicase B. In this study, we purified DNA helicase B from mouse FM3A cells and determined partial amino acid sequences of the purified protein. By using a DNA probe synthesized according to one of the partial amino acid sequences, a cDNA was isolated, which encoded a 121.5 kDa protein containing seven conserved motifs for DNA/RNA helicase superfamily members. A database search revealed similarity between DNA helicase B and the alpha subunit of exodeoxyribonuclease V of a number of prokaryotes including Escherichia coli RecD protein, but no homologous protein was found in yeast. The cDNA encoding DNA helicase B from tsFT848 was sequenced and a mutation was found between DNA/RNA helicase motifs IV and V.

Migration of a Holliday junction through a nucleosome directed by the E. coli RuvAB motor protein

Chromatin plays a critical role in regulating access to DNA by proteins that direct recombination and repair. The E. coli RuvAB protein complex promotes branch migration of the Holliday junction recombination intermediate. The ability of RuvAB to negotiate passage of the junction through nucleosomal DNA is examined. The model system involves the formation of a Holliday junction positioned upstream of a nucleosome. Unassisted, the junction is blocked by a histone octamer. In the presence of RuvAB and ATP, rapid branch migration through the nucleosome is observed. It results in disruption of the histone-DNA interactions leading to the removal of the octamer from the junction intermediate. These results suggest that eukaryotic DNA motor proteins analogous to RuvAB could function during recombination to promote branch migration through chromatin.