Inhibition of protein-mediated homologous pairing by a DNA helicase.

Protein-mediated exchange of homologous DNA strands is a central reaction in general genetic recombination and the mechanism by which proteins mediate this process in vivo is a topic of keen interest. The dda protein of the bacteriophage T4 is a DNA helicase that has been shown to accelerate branch migration catalyzed by the phage uvsX and gene 32 proteins in vitro (Kodadek, T., and Alberts, B.M. (1987) Nature 326, 312-314). This study did not address the potential role of the helicase in protein-mediated homologous pairing, the first phase of the overall strand-exchange reaction. It is shown here that the dda protein inhibits uvsX protein-mediated pairing between homologous single and double-stranded DNAs. Experiments using deproteinized heteroduplex joints demonstrate that the dda helicase is capable of unwinding these structures to some extent and suggests that this activity may be responsible for the observed inhibition of pairing. It is found that the helicase also reduces the level of uvsX protein-mediated, single-stranded DNA-dependent ATP hydrolysis in the strand-exchange reactions, suggesting that the helicase may also act to destabilize the uvsX protein-DNA filaments that are important intermediates in the pairing reaction. Three other helicases are found to have no effect on the uvsX protein-mediated pairing reaction. A model rationalizing the ability of the dda protein to both inhibit homologous pairing and stimulate branch migration is presented and possible in vivo roles for this interesting activity are discussed.     

Bound Lac repressor protein differentially inhibits the unwinding reactions catalyzed by DNA helicases.

A partial duplex DNA substrate containing the Lac repressor binding site, within the duplex region, was constructed to examine the effect of bound Lac repressor on the unwinding reaction catalyzed by several DNA helicases. The substrate contained 90 base pairs of double-stranded DNA and, in the absence of Lac repressor, was effectively unwound by each of the seven helicases tested. The unwinding reactions catalyzed by Escherichia coli Rep protein, bacteriophage T4 Dda protein and E. coli DNA helicase I were not inhibited by the presence of bound Lac repressor. Both SV40 T antigen and E. coli helicase II were partially inhibited by bound repressor at the highest repressor concentrations tested. The helicase reactions catalyzed by E. coli DnaB protein and helicase IV were substantially inhibited by the presence of bound protein. When the length of the duplex region was increased to 323 base pairs the inhibition spectrum caused by bound Lac repressor on the unwinding reactions catalyzed by DnaB protein, helicase I and helicase II was essentially the same as that observed using the shorter partial duplex molecule. Inhibition of the unwinding reaction was due to the presence of bound Lac repressor as evidenced by the substantially weaker inhibition of helicase IV by Lac repressor in the presence of IPTG. In addition, we have shown that Rep protein displaces the bound repressor protein during the course of an unwinding reaction.     

Escherichia coli DNA helicases: mechanisms of DNA unwinding

DNA helicases are ubiquitous enzymes that catalyse the unwinding of duplex DNA during replication, recombination and repair. These enzymes have been studied extensively; however, the specific details of how any helicase unwinds duplex DNA are unknown. Although it is clear that not all helicases unwind duplex DNA in an identical way, many helicases possess similar properties, which are thus likely to be of general importance to their mechanism of action. For example, since helicases appear generally to be oligomeric enzymes, the hypothesis is presented in this review that the functionally active forms of DNA helicases are oligomeric. The oligomeric nature of helicases provides them with multiple DNA-binding sites, allowing the transient formation of ternary structures, such that at an unwinding fork, the helicase can bind either single-stranded and duplex DNA simultaneously or two strands of single-stranded DNA. Modulation of the relative affinities of these binding sites for single-stranded versus duplex DNA through ATP binding and hydrolysis would then provide the basis for a cycling mechanism for processive unwinding of DNA by helicases. The properties of the Escherichia coli DNA helicases are reviewed and possible mechanisms by which helicases might unwind duplex DNA are discussed in view of their oligomeric structures, with emphasis on the E. coli Rep, RecBCD and phage T7 gene 4 helicases.     

Inhibition of DNA helicase II unwinding and ATPase activities by DNA-interacting ligands. Kinetics and specificity.

Although DNA helicases play important roles in the processing of DNA, little is known about the effects of DNA-interacting ligands on these helicases. Therefore, the effects of a wide variety of DNA-binding ligands on the unwinding and ATPase reactions catalyzed by Escherichia coli DNA helicase II were examined. DNA minor groove binders and simple DNA intercalators did not inhibit helicase II. However, DNA intercalators, such as mitoxantrone and nogalamycin, which position functionalities in the major groove upon binding duplex DNA, were potent inhibitors of helicase II. To determine the mechanism by which mitoxantrone inhibited helicase II, the unwinding and DNA-dependent ATPase activities of helicase II were measured using a spectrum of double- and single-stranded DNA substrates. Using either a 71-base pair (bp) M13mp7 partially duplexed DNA substrate or a 245-bp bluntended, fully duplexed DNA substrate, the apparent Ki value for inhibition by mitoxantrone of both the unwinding and ATPase reactions was approximately 1 microM for both substrates, suggesting that the mechanism of inhibition of helicase II by mitoxantrone is the same for both substrates and requires the presence of double-stranded structure. To strengthen this conclusion, the ability of mitoxantrone to inhibit the DNA-dependent ATPase activity of helicase II was determined using two single-stranded substrates, poly(dT) and the 245-bp substrate after heat denaturation. Using either substrate, mitoxantrone inhibited the ATPase activity of helicase II far less effectively. Thus, these results indicate that the intercalation of mitoxantrone into double-stranded DNA, with accompanying placement of functionalities in the major groove, generates a complex that impedes helicase II, resulting in both inhibition of ATP hydrolysis and unwinding activity. Furthermore, we report here that DNA-binding ligands inhibit the unwinding activity of helicases I and IV and Rep protein from E. coli, demonstrating that the inhibition observed for helicase II is not unique to this enzyme.     

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.     

Unraveling DNA helicases. Motif, structure, mechanism and function.

DNA helicases are molecular 'motor' enzymes that use the energy of NTP hydrolysis to separate transiently energetically stable duplex DNA into single strands. They are therefore essential in nearly all DNA metabolic transactions. They act as essential molecular tools for the cellular machinery. Since the discovery of the first DNA helicase in Escherichia coli in 1976, several have been isolated from both prokaryotic and eukaryotic systems. DNA helicases generally bind to ssDNA or ssDNA/dsDNA junctions and translocate mainly unidirectionally along the bound strand and disrupt the hydrogen bonds between the duplexes. Most helicases contain conserved motifs which act as an engine to drive DNA unwinding. Crystal structures have revealed an underlying common structural fold for their function. These structures suggest the role of the helicase motifs in catalytic function and offer clues as to how these proteins can translocate and unwind DNA. The genes containing helicase motifs may have evolved from a common ancestor. In this review we cover the conserved motifs, structural information, mechanism of DNA unwinding and translocation, and functional aspects of DNA helicases.     

DNA synthesis at a fork in the presence of DNA helicases

In a mixture of Escherichia coli DNA polymerase III holoenzyme, single-strand-binding protein, artificially forked lambda bacteriophage DNA with primer annealed to the leading side of the fork, dNTPs and ATP, DNA synthesis is enhanced by helicase II, less so by helicases, I, III or rep protein of E. coli or T4 phage helicase. The effect of helicase II depends on ATP, it is enhanced by helicase III, and it is not observed using DNA polymerase I or T4 DNA polymerase. In the absence of dNTPs helicase II is less active than helicase I or T4 helicase in unwinding the forked DNA. We believe that helicase II both shifts the forks and stimulates DNA polymerase III. The results support the conclusion derived from previous studies that helicase II is part of the DNA-synthesizing system of E. coli.     

Nucleic acid unwinding by hepatitis C virus and bacteriophage t7 helicases is sensitive to base pair stability

Helicases are motor enzymes that convert the chemical energy of NTP hydrolysis into mechanical force for motion and nucleic acid strand separation. Within the cell, helicases process a range of nucleic acid sequences. It is not known whether this composite rate of moving and opening the strands of nucleic acids depends on the base sequence. Our presteady state kinetic studies of helicases from two classes, the ring-shaped T7 helicase and two forms of non-ring-shaped hepatitis C virus (HCV) helicase, show that both the unwinding rate and processivity depend on the sequence and decrease as the nucleic acid stability increases. The DNA unwinding activity of T7 helicase and the RNA unwinding activity of HCV helicases decrease steeply with increasing base pair stability. On the other hand, the DNA unwinding activity of HCV helicases is less sensitive to base pair stability. These results predict that helicases will fall into a spectrum of modest to high sensitivity to base pair stability depending on their biological role in the cell. Modeling of the dependence provided the degree of the active involvement of helicase in base pair destabilization during the unwinding process and distinguished between passive and active mechanisms of unwinding.     

E. coli Rep oligomers are required to initiate DNA unwinding in vitro.

E. coli Rep protein is a 3' to 5' SF1 superfamily DNA helicase which is monomeric in the absence of DNA, but can dimerize upon binding either single-stranded or duplex DNA. A variety of biochemical studies have led to proposals that Rep dimerization is important for its helicase activity; however, recent structural studies of Bacillus stearothermophilus PcrA have led to suggestions that SF1 helicases, such as E. coli Rep and E. coli UvrD, function as monomeric helicases. We have examined the question of whether Rep oligomerization is important for its DNA helicase activity using pre-steady state stopped-flow and chemical quenched-flow kinetic studies of Rep-catalyzed DNA unwinding. The results from four independent experiments demonstrate that Rep oligomerization is required for initiation of DNA helicase activity in vitro. No DNA unwinding is observed when only a Rep monomer is bound to the DNA substrate, even when fluorescent DNA substrates are used that can detect partial unwinding of the first few base-pairs at the ss-ds-DNA junction. In fact, under these conditions, ATP hydrolysis causes dissociation of the Rep monomer from the DNA, rather than DNA unwinding. These studies demonstrate that wild-type Rep monomers are unable to initiate DNA unwinding in vitro, and that oligomerization is required.     

DNA repair and replication fork helicases are differentially affected by alkyl phosphotriester lesion

DNA helicases are directly responsible for catalytically unwinding duplex DNA in an ATP-dependent and directionally specific manner and play essential roles in cellular nucleic acid metabolism. It has been conventionally thought that DNA helicases are inhibited by bulky covalent DNA adducts in a strand-specific manner. However, the effects of highly stable alkyl phosphotriester (PTE) lesions that are induced by chemical mutagens and refractory to DNA repair have not been previously studied for their effects on helicases. In this study, DNA repair and replication helicases were examined for unwinding a forked duplex DNA substrate harboring a single isopropyl PTE specifically positioned in the helicase-translocating or -nontranslocating strand within the double-stranded region. A comparison of SF2 helicases (RecQ, RECQ1, WRN, BLM, FANCJ, and ChlR1) with a SF1 DNA repair helicase (UvrD) and two replicative helicases (MCM and DnaB) demonstrates unique differences in the effect of the PTE on the DNA unwinding reactions catalyzed by these enzymes. All of the SF2 helicases tested were inhibited by the PTE lesion, whereas UvrD and the replication fork helicases were fully tolerant of the isopropyl backbone modification, irrespective of strand. Sequestration studies demonstrated that RECQ1 helicase was trapped by the PTE lesion only when it resided in the helicase-translocating strand. Our results are discussed in light of the current models for DNA unwinding by helicases that are likely to encounter sugar phosphate backbone damage during biological DNA transactions.     

Construction and characterization of a site-directed CC-1065-N3-adenine adduct within a 117 base pair DNA restriction fragment

The design, construction, and characterization of a site-directed CC-1065-N3-adenine adduct in a 117 base pair segment of M13mpI DNA are described. CC-1065 is an extremely potent antitumor antibiotic produced by Streptomyces zelensis. Previous studies have demonstrated that the cyclopropyl ring of CC-1065 reacts quite specifically with N3 of adenine in double-stranded DNA to form a CC-1065-DNA adduct. Following alkylation, the drug molecule lies snugly within the minor groove of DNA, overlapping with five base pairs for which a marked sequence preference exists [Hurley, L. H., Reynolds, V. R., Swenson, D. H., Petzold, G. L., & Scahill, T. A. (1984) Science (Washington, D.C.) 226, 843-844]. On the basis of the unique characteristics of the reaction of CC-1065 with DNA and the structure of the resulting DNA adduct, we have designed a general strategy to construct a site-directed CC-1065-DNA adduct in a restriction fragment. The presence of unique AluI and HaeIII restriction enzymes sites on each side of a high-affinity CC-1065 binding sequence (5'-GATTA) permitted the preparation of a partial duplex DNA molecule containing the CC-1065 binding sequence in the duplex DNA region. Since CC-1065 only binds to duplex DNA, potential CC-1065 binding sequences in the long single-stranded regions were protected from drug binding during the construction process.(ABSTRACT TRUNCATED AT 250 WORDS)     

ABC excinuclease incises both 5' and 3' to the CC-1065-DNA adduct and its incision activity is stimulated by DNA helicase II and DNA polymerase I

CC-1065 is a large molecule that binds covalently to adenine residues of DNA in a sequence-specific manner and lies in the minor groove about four bases to the 5' side of the adducted residue. Using a reconstituted Escherichia coli nucleotide excision repair system, we have obtained data showing that the ABC excinuclease makes incisions both 5' and 3' to the CC-1065 adduct and that the incision activity is stimulated by the addition of helicase II and DNA polymerase I (and dNTPs). Our results with the CC-1065 adduct are consistent with the reported in vitro processing of other adducts (e.g., cisplatin, UV photoproducts) but do not agree with a recent study that reported anomalous processing of the CC-1065 adduct by ABC excinuclease and helicase II. Our results also imply that, in binding to damaged DNA, ABC excinuclease does not make important contacts in the minor groove four bases to the 5' side of the damaged residue.     

Escherichia coli helicase II (uvrD) protein can completely unwind fully duplex linear and nicked circular DNA

We have examined the duplex DNA unwinding (helicase) properties of the Escherichia coli helicase II protein (uvrD gene product) over a wide range of protein concentrations and solution conditions using a variety of duplex DNA substrates including fully duplex blunt ended and nicked circular molecules. We find that helicase II protein is able to initiate on and completely unwind fully duplex DNA molecules without the requirement for a covalently attached 3' single-stranded DNA tail. This DNA unwinding activity is dependent upon Mg2+ and ATP and requires that the amount of protein be in excess of that needed to saturate the resulting single-stranded DNA. Unwinding experiments on fully duplex blunt ended DNA with lengths of 341, 849, 1625, and 2671 base pairs indicate that unwinding occurs at the same high ratios of helicase II protein/nucleotide, independent of DNA length (50% unwinding requires approximately 0.6 helicase II monomers/nucleotide in 2.5 mM MgCl2, 10% glycerol, pH 7.5, 37 degrees C). Helicase II protein is also able to unwind completely a nicked circular DNA molecule containing 2671 base pairs. At lower but still high molar ratios of helicase II protein to DNA, duplex DNA molecules containing a single-stranded (ss) region attached to a 3' end of the duplex are preferentially unwound in agreement with the results obtained by S. W. Matson [1986) J. Biol. Chem. 261, 10169-10175). This preferential unwinding of duplex DNA with an attached 3' ssDNA most likely reflects the availability of a high affinity site (ssDNA) with the proper orientation for initiation; however, this may not reflect the type of DNA molecule upon which helicase II protein initiates DNA unwinding in vivo. The effects of changes in NaCl, NaCH3COO, and MgCl2 concentration on the ability of helicase II protein to unwind fully duplex DNA and duplex DNA with a 3' ssDNA tail have also been examined. Although the unwinding of fully duplex and nicked circular DNA molecules reported here occurs at higher helicase II protein to DNA ratios than have been previously used in most studies of this protein in vitro, this activity is likely to be relevant to the function of this protein in vivo since very high levels of helicase II protein accumulate in E. coli during the SOS response to DNA damage (approximately 2-5 x 10(4) copies/cell).(ABSTRACT TRUNCATED AT 400 WORDS)     

Identification and purification of a protein that stimulates the helicase activity of the Escherichia coli Rep protein

A polypeptide (Mr = 15,000) has been purified from Escherichia coli cell extracts that significantly stimulates the duplex DNA unwinding reaction catalyzed by E. coli Rep protein. The Rep helicase unwinding reaction was stimulated by as much as 20-fold, upon addition of the stimulatory protein, using either a 71-base pair or a 343-base pair partial duplex DNA molecule as a substrate. The purified Rep helicase stimulatory protein (RHSP) had no intrinsic helicase activity or ATP hydrolysis activity and did not stimulate the single-stranded DNA-dependent ATP hydrolysis reaction catalyzed by Rep protein. It is likely that RHSP stimulates the Rep helicase unwinding reaction by stoichiometric binding to single-stranded DNA. However, a specific interaction between Rep protein and RHSP cannot be ruled out, since RHSP did not stimulate the duplex DNA unwinding reactions catalyzed by E. coli helicase I or the recently discovered 75-kDa helicase. RHSP did stimulate the duplex DNA unwinding reaction catalyzed by E. coli helicase II. The identification and subsequent purification of RHSP from cell extracts demonstrates the feasibility of using direct helicase assays to purify stimulatory proteins.     

Escherichia coli RecQ is a rapid, efficient, and monomeric helicase

RecQ family helicases play a key role in chromosome maintenance. Despite extensive biochemical, biophysical, and structural studies, the mechanism by which helicase unwinds double-stranded DNA remains to be elucidated. Using a wide array of biochemical and biophysical approaches, we have previously shown that the Escherichia coli RecQ helicase functions as a monomer. In this study, we have further characterized the kinetic mechanism of the RecQ-catalyzed unwinding of duplex DNA using the fluorometric stopped-flow method based on fluorescence resonance energy transfer. Our results show that RecQ helicase binds preferentially to 3'-flanking duplex DNA. Under the pre-steady-state conditions, the burst amplitude reveals a 1:1 ratio between RecQ and DNA substrate, suggesting that an active monomeric form of RecQ helicase is involved in the catalysis. Under the single-turnover conditions, the RecQ-catalyzed unwinding is independent of the 3'-tail length, indicating that functional interactions between RecQ molecules are not implicated in the DNA unwinding. It was further determined that RecQ unwinds DNA rapidly with a step size of 4 bp and a rate of approximately 21 steps/s. These kinetic results not only further support our previous conclusion that E. coli RecQ functions as a monomer but also suggest that some of the Superfamily 2 helicases may function through an "inchworm" mechanism.     

Measurement of steady-state kinetic parameters for DNA unwinding by the bacteriophage T4 Dda helicase: use of peptide nucleic acids to trap single-stranded DNA products of helicase reactions

Measurement of steady-state rates of unwinding of double-stranded oligonucleotides by helicases is hampered due to rapid reannealing of the single-stranded DNA products. Including an oligonucleotide in the reaction mixture which can hybridize with one of the single strands can prevent reannealing. However, helicases bind to single-stranded DNA, therefore the additional oligonucleotide can sequester the enzyme, leading to slower observed rates for unwinding. To circumvent this problem, the oligonucleotide that serves as a trap was replaced with a strand of peptide nucleic acid (PNA). Fluorescence polarization was used to determine that a 15mer PNA strand does not bind to the bacteriophage T4 Dda helicase. Steady-state kinetic parameters of unwinding catalyzed by Dda were determined by using PNA as a trapping strand. The substrate consisted of a partial duplex with 15 nt of single-stranded DNA and 15 bp. In the presence of 250 nM substrate and 1 nM Dda, the rate of unwinding in the presence of the DNA trapping strand was 0.30 nM s^–1 whereas the rate was 1.34 nM s^–1 in the presence of the PNA trapping strand. PNA prevents reannealing of single-stranded DNA products, but does not sequester the helicase. This assay will prove useful in defining the complete kinetic mechanism for unwinding of oligonucleotide substrates by this helicase.     

Two steps forward,one step back: Determining XPD helicase mechanism by single-molecule fluorescence and high-resolution optical tweezers

XPD-like helicases constitute a prominent DNA helicase family critical for many aspects of genome maintenance. These enzymes share a unique structural feature, an auxiliary domain stabilized by an iron-sulphur (FeS) cluster, and a 5′–3′ polarity of DNA translocation and duplex unwinding. Biochemical analyses alongside two single-molecule approaches, total internal reflection fluorescence microscopy and high-resolution optical tweezers, have shown how the unique structural features of XPD helicase and its specific patterns of substrate interactions tune the helicase for its specific cellular function and shape its molecular mechanism. The FeS domain forms a duplex separation wedge and contributes to an extended DNA binding site. Interactions within this site position the helicase in an orientation to unwind the duplex, control the helicase rate, and verify the integrity of the translocating strand. Consistent with its cellular role, processivity of XPD is limited and is defined by an idiosyncratic stepping kinetics. DNA duplex separation occurs in single base pair steps punctuated by frequent backward steps and conformational rearrangements of the protein–DNA complex. As such, the helicase in isolation mainly stabilizes spontaneous base pair opening and exhibits a limited ability to unwind stable DNA duplexes. The presence of a cognate ssDNA binding protein converts XPD into a vigorous helicase by destabilizing the upstream dsDNA as well as by trapping the unwound strands. Remarkably, the two proteins can co-exist on the same DNA strand without competing for binding. The current model of the XPD unwinding mechanism will be discussed along with possible modifications to this mechanism by the helicase interacting partners and unique features of such bio-medically important XPD-like helicases as FANCJ (BACH1), RTEL1 and CHLR1 (DDX11).     

A helicase assay based on the displacement of fluorescent, nucleic acid-binding ligands.

We have developed a new helicase assay that overcomes many limitations of other assays used to measure this activity. This continuous, kinetic assay is based on the displacement of fluorescent dyes from dsDNA upon DNA unwinding. These ligands exhibit significant fluorescence enhancement when bound to duplex nucleic acids and serve as the reporter molecules of DNA unwinding. We evaluated the potential of several dyes [acridine orange, ethidium bromide, ethidium homodimer, bis-benzimide (DAPI), Hoechst 33258 and thiazole orange] to function as suitable reporter molecules and demonstrate that the latter three dyes can be used to monitor the helicase activity of Escherichia coli RecBCD enzyme. Both the binding stoichiometry of RecBCD enzyme for the ends of duplex DNA and the apparent rate of unwinding are not significantly perturbed by two of these dyes. The effects of temperature and salt concentration on the rate of unwinding were also examined. We propose that this dye displacement assay can be readily adapted for use with other DNA helicases, with RNA helicases, and with other enzymes that act on nucleic acids.     

Domain requirements for DNA unwinding by mycobacterial UvrD2, an essential DNA helicase

Mycobacterial UvrD2 is a DNA-dependent ATPase with 3' to 5' helicase activity. UvrD2 is an atypical helicase, insofar as its N-terminal ATPase domain resembles the superfamily I helicases UvrD/PcrA, yet it has a C-terminal HRDC domain, which is a feature of RecQ-type superfamily II helicases. The ATPase and HRDC domains are connected by a CxxC-(14)-CxxC tetracysteine module that defines a new clade of UvrD2-like bacterial helicases found only in Actinomycetales. By characterizing truncated versions of Mycobacterium smegmatis UvrD2, we show that whereas the HRDC domain is not required for ATPase or helicase activities in vitro, deletion of the tetracysteine module abolishes duplex unwinding while preserving ATP hydrolysis. Replacing each of the CxxC motifs with a double-alanine variant AxxA had no effect on duplex unwinding, signifying that the domain module, not the cysteines, is crucial for function. The helicase activity of a truncated UvrD2 lacking the tetracysteine and HRDC domains was restored by the DNA-binding protein Ku, a component of the mycobacterial NHEJ system and a cofactor for DNA unwinding by the paralogous mycobacterial helicase UvrD1. Our findings indicate that coupling of ATP hydrolysis to duplex unwinding can be achieved by protein domains acting in cis or trans. Attempts to disrupt the M. smegmatis uvrD2 gene were unsuccessful unless a second copy of uvrD2 was present elsewhere in the chromosome, indicating that UvrD2 is essential for growth of M. smegmatis.