DNA binding activity of Helicobacter pylori DnaB helicase: the role of the N-terminal domain in modulating DNA binding activities

Replicative helicases are major motor proteins essential for chromosomal DNA replication in prokaryotes. Usually hexameric in solution, their DNA binding property must have different roles at stages ranging from the loading onto a branched structure at initiation from the origin to the highly processive translocation during elongation. Here, we have analysed the DNA binding activity of Helicobacter pylori (Hp) replicative helicase, DnaB. The results indicate that while the C-terminal region is important for its DNA binding activity, the N-terminus appears to dampen the protein's affinity for DNA. The masking activity of the N-terminus does not require ATP or hexamerization of HpDnaB and can be overcome by deleting the N-terminus. It can also be neutralized by engaging the N-terminus in an interaction with a partner like the C-terminus of DnaG primase. The inhibitory effect of the N-terminus on DNA binding activity is consistent with the 3D homology model of HpDnaB. Electron microscopy of the HpDnaB-ssDNA complex showed that HpDnaB preferentially bound at the ends of linear ssDNA and translocated along the DNA in the presence of ATP. These results provide an insight into the stimulatory and inhibitory effects of different regions of HpDnaB on DNA binding activities that may be central to the loading and translocation functions of DnaB helicases.     

DNA helicase activity of the RecD protein from Deinococcus radiodurans

The bacterium Deinococcus radiodurans is extremely resistant to high levels of DNA-damaging agents, including gamma rays and ultraviolet light that can lead to double-stranded DNA breaks. Surprisingly, the organism does not appear to have a RecBCD enzyme, an enzyme that is critical for double-strand break repair in many other bacteria. The D. radiodurans genome does encode a protein whose closest characterized homologues are RecD subunits of RecBCD enzymes in other bacteria. We have purified this novel D. radiodurans RecD protein and characterized its biochemical activities. The D. radiodurans RecD protein is a DNA helicase that unwinds short (20 base pairs) DNA duplexes with either a 5'-single-stranded tail or a forked end, but not blunt-ended or 3'-tailed duplexes. Duplexes with 10-12 nucleotide (nt) 5'-tails are good unwinding substrates and are bound tightly, while DNA with shorter tails (4-8 nt) are poor unwinding substrates and are bound much less tightly. The RecD protein is much less efficient at unwinding slightly longer substrates (52 or 76 base pairs, with 12 nt 5'-tails). Unwinding of the longer substrates is stimulated somewhat (4-5-fold) by the single-stranded DNA-binding protein from D. radiodurans. These results show that the D. radiodurans RecD protein is a DNA helicase with 5'-3' polarity and low processivity.     

The role of Bacillus anthracis RecD2 helicase in DNA mismatch repair

DNA mismatch repair (MMR) systems can be classified as either MutH-dependent or MutH-independent. In bacteria, extensive studies have been conducted with the MutH-dependent MMR in Escherichia coli and its close relatives. The picture of MutH-independent MMR in other bacteria is less clear, as MMR components other than MutS and MutL have not been identified in the majority of bacteria. Bacillus anthracis is one of the MutH-less Gram(+) bacteria in the phylum of Firmicutes. We used papillation as a tool to search for B. anthracis new mutator strains and identified a spontaneous mutator that carries a minitransposon insertion in the BAS4289 locus. The mutational frequency and specificity exhibited in this mutant were comparable to that of MMR-deficient strains with knockouts of mutL or mutS. It retained a similar UV sensitivity profile as that of the wild type. BAS4289 encodes a putative DNA helicase RecD2 that shares 30% sequence identity with Deinococcus radiodurans RecD2, a well characterized superfamily 1B helicase whose homologs are widely present in Firmicutes complete genomes. We demonstrated that the N-terminal region of RecD2, a unique sequence extension used to distinguish RecD2 from RecD1, was important for B. anthracis RecD2, as mutations in the N-terminal conserved motifs affected its DNA repair function. This is the first report of a RecD2 helicase being associated with MMR. RecD2 and our recently described YycJ protein are likely to be two additional components in the B. anthracis MutH-independent MMR system.     

Regulation of translocation polarity by helicase domain 1 in SF2B helicases

Structurally similar superfamily I (SF1) and II (SF2) helicases translocate on single-stranded DNA (ssDNA) with defined polarity either in the 5'-3' or in the 3'-5' direction. Both 5'-3' and 3'-5' translocating helicases contain the same motor core comprising two RecA-like folds. SF1 helicases of opposite polarity bind ssDNA with the same orientation, and translocate in opposite directions by employing a reverse sequence of the conformational changes within the motor domains. Here, using proteolytic DNA and mutational analysis, we have determined that SF2B helicases bind ssDNA with the same orientation as their 3'-5' counterparts. Further, 5'-3' translocation polarity requires conserved residues in HD1 and the FeS cluster containing domain. Finally, we propose the FeS cluster-containing domain also provides a wedge-like feature that is the point of duplex separation during unwinding.     

Mapping the DNA topoisomerase III binding domain of the Sgs1 DNA helicase

Several members of the RecQ family of DNA helicases are known to interact with DNA topoisomerase III (Top3). Here we show that the Saccharomyces cerevisiae Sgs1 and Top3 proteins physically interact in cell extracts and bind directly in vitro. Sgs1 and Top3 proteins coimmunoprecipitate from cell extracts under stringent conditions, indicating that Sgs1 and Top3 are present in a stable complex. The domain of Sgs1 which interacts with Top3 was identified by expressing Sgs1 truncations in yeast. The results indicate that the NH(2)-terminal 158 amino acids of Sgs1 are sufficient for the high affinity interaction between Sgs1 and Top3. In vitro assays using purified Top3 and NH(2)-terminal Sgs1 fragments demonstrate that at least part of the interaction is through direct protein-protein interactions with these 158 amino acids. Consistent with these physical data, we find that mutant phenotypes caused by a point mutation or small deletions in the Sgs1 NH(2) terminus can be suppressed by Top3 overexpression. We conclude that Sgs1 and Top3 form a tight complex in vivo and that the first 158 amino acids of Sgs1 are necessary and sufficient for this interaction. Thus, a primary role of the Sgs1 amino terminus is to mediate the Top3 interaction.     

Properties of the PriA helicase domain and its role in binding PriA to specific DNA structures

Primosome assembly protein PriA functions in the assembly of the replisome at forked DNA structures. Whereas its N-terminal DNA binding domain (DBD) binds independently to DNA, the affinity of DBD protein for forked structures is relatively weak. Although the PriA helicase domain (HD) is required for high affinity fork binding, HD protein had very low affinity for DNA. It had only low levels of ATPase activity, and it hydrolyzed ATP when DNA was absent whereas PriA did not. HD catalyzed unwinding of a minimal substrate composed of a duplex with a 3' single-stranded tail. Single-strand binding protein (SSB) bound to the tail of this substrate inhibited this reaction by full-length PriA but enhanced the reaction by HD. SSB stabilized binding of PriA but not of DBD or HD to duplexes with a 5' or 3' single-stranded tail. On forked substrates SSB enhanced helicase action on the lagging-strand arm by PriA but not by HD. The results indicate that synergy of the DBD and HD allows stable binding at the interface between duplex and single-stranded DNA bound by SSB. This mode of binding may be analogous to fork binding, which orients the helicase to act on the lagging-strand side of the fork.     

The N-terminal domain of TWINKLE contributes to single-stranded DNA binding and DNA helicase activities

The TWINKLE protein is a hexameric DNA helicase required for replication of mitochondrial DNA. TWINKLE displays striking sequence similarity to the bacteriophage T7 gene 4 protein (gp4), which is a bi-functional primase-helicase required at the phage DNA replication fork. The N-terminal domain of human TWINKLE contains some of the characteristic sequence motifs found in the N-terminal primase domain of the T7 gp4, but other important motifs are missing. TWINKLE is not an active primase in vitro and the functional role of the N-terminal region has remained elusive. In this report, we demonstrate that the N-terminal part of TWINKLE is required for efficient binding to single-stranded DNA. Truncations of this region reduce DNA helicase activity and mitochondrial DNA replisome processivity. We also find that the gp4 and TWINKLE are functionally distinct. In contrast to the phage protein, TWINKLE binds to double-stranded DNA. Moreover, TWINKLE forms stable hexamers even in the absence of Mg²⁺ or NTPs, which suggests that an accessory protein, a helicase loader, is needed for loading of TWINKLE onto the circular mtDNA genome.     

The T4 phage SF1B helicase Dda is structurally optimized to perform DNA strand separation

Helicases move on DNA via an ATP binding and hydrolysis mechanism coordinated by well-characterized helicase motifs. However, the translocation along single-stranded DNA (ssDNA) and the strand separation of double-stranded (dsDNA) may be loosely or tightly coupled. Dda is a phage T4 SF1B helicase with sequence homology to the Pif1 family of helicases that tightly couples translocation to strand separation. The crystal structure of the Dda-ssDNA binary complex reveals a domain referred to as the "pin" that was previously thought to remain static during strand separation. The pin contains a conserved phenylalanine that mediates a transient base-stacking interaction that is absolutely required for separation of dsDNA. The pin is secured at its tip by protein-protein interactions through an extended SH3 domain thereby creating a rigid strut. The conserved interface between the pin and the SH3 domain provides the mechanism for tight coupling of translocation to strand separation.     

Further characterization of DNA helicase activity of mouse DNA-dependent adenosinetriphosphatase B (DNA helicase B)

The DNA helicase activity of DNA-dependent ATPase B purified from mouse FM3A cells [Seki, M., Enomoto, T., Hanaoka, F., & Yamada, M. (1987) Biochemistry 26, 2924-2928] has been further characterized. The helicase activity was assayed with partially duplex DNA substrates in which oligonucleotides to be released by the enzyme were radiolabeled. Oligonucleotides with or without phosphate at the 5' termini or with a deoxy- or dideoxyribose at the 3'-terminal nucleotides were displaced by this enzyme with essentially the same efficiency and with the same ATP (and dATP) and Mg2+ requirements. Thus, there was no strict structure requirement for both ends of duplex regions of substrates to be unwound by the enzyme. Shorter strands were released more readily than longer strands up to the length of 140 bases. The attachment of the enzyme to a single-stranded DNA region was a prerequisite for the neighboring duplex to be unwound; the enzyme-catalyzed unwinding was inhibited competitively by the coaddition of single-stranded DNAs which act as cofactors of the ATPase activity. Their activities as the inhibitor of helicase were well correlated with those as the cofactor of ATPase. The helicase B was found to migrate along single-stranded DNA in the 5' to 3' direction by the use of single strands with short duplex regions at both 3' and 5' ends as substrate. A possible role of this enzyme in DNA replication in mammalian cells is discussed.     

DNA binding by the substrate specificity (wedge) domain of RecG helicase suggests a role in processivity

RecG differs from most helicases acting on branched DNA in that it is thought to catalyze unwinding via translocation of a monomer on dsDNA, with a wedge domain facilitating strand separation. Conserved phenylalanines in the wedge are shown to be critical for DNA binding. When detached from the helicase domains, the wedge bound a Holliday junction with high affinity but failed to bind a replication fork structure. Further stabilizing contacts are identified in full-length RecG, which may explain fork binding. Detached from the wedge, the helicase region unwound junctions but had extremely low substrate affinity, arguing against the "classical inchworm" mode of translocation. We propose that the processivity of RecG on branched DNA substrates is dependent on the ability of the wedge to establish strong binding at the branch point. This keeps the helicase motor in contact with the substrate, enabling it to drive dsDNA translocation with high efficiency.     

DNA helicase RepA: cooperative ATPase activity and binding of nucleotides

The steady-state kinetic parameters of the ATPase activity of the homohexameric DNA helicase RepA and the binding of the fluorescent analogue epsilonADP to RepA have been studied. ssDNA stimulates RepA ATPase activity optimally at acidic pH 5.3-6.0. The sigmoidal kinetic curves in both the absence and presence of ssDNA show strong positive cooperativity for ATP hydrolysis, with oligonucleotides longer than 10mer optimal for ssDNA-stimulated ATPase activity. Fluorescence titrations show that, at 25 degrees C and in the absence of DNA, the binding of epsilonADP to RepA is biphasic with three high (K(1) = 1.54 x 10(6) M(-1)) and three low (K(2) = 4.71 x 10(4) M(-)(1)) affinity binding sites differing by 30-40-fold in binding constants. In the absence of cofactors, RepA melts cooperatively at T(m) = 65.8 +/- 0.1 degrees C and is more stable in the presence of ATPgammaS, T(m) = 68.1 +/- 0.2 degrees C (DeltaDeltaG 0.95 kcal/mol), than in the presence of ADP, T(m) = 66. 5 +/- 0.1 degrees C (DeltaDeltaG 0.29 kcal/mol), indicating that the additional phosphate group in ATPgammaS has a significant influence on RepA structure. A model is proposed in which individual subunits of RepA sequentially and cooperatively perform a multistep ATP hydrolytic cycle.     

The conserved B3 domain of VIVIPAROUS1 has a cooperative DNA binding activity.

The biochemical activities that underlie the genetically defined activator and repressor functions of the VIVIPAROUS1 (VP1) protein have resisted in vitro analysis. Here, we show that a glutathione S-transferase (GST) fusion protein, including only the highly conserved B3 domain of VP1, has a highly cooperative, sequence-specific DNA binding activity. GST fusion proteins that include larger regions of the VP1 protein have very low activity, indicating that removal of the flanking protein sequences is necessary to elicit DNA binding in vitro. DNA competition and DNase I footprinting analyses show that B3 binds specifically to the Sph element involved in VP1 activation of the C1 gene, whereas binding to the G-box-type VP1-responsive element is of low affinity and is nonspecific. Footprint analysis of the C1 promoter revealed that sequences flanking the core TCCATGCAT motif of Sph also contribute to the recognition of the Sph element in its native context. The salient features of the in vitro GST-B3 DNA interaction are in good agreement with the protein and DNA sequence requirements defined by the functional analyses of VP1 and VP1-responsive elements in maize cells.     

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 α 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.     

Mechanism of DNA binding by the DnaB helicase of Escherichia coli: analysis of the roles of domain gamma in DNA binding.

We have analyzed the mechanism of single-stranded DNA (ssDNA) binding mediated by the C-terminal domain gamma of the DnaB helicase of Escherichia coli. Sequence analysis of this domain indicated a specific basic region, "RSRARR", and a leucine zipper motif that are likely involved in ssDNA binding. We have carried out deletion as well as in vitro mutagenesis of specific amino acid residues in this region in order to determine their function(s) in DNA binding. The functions of the RSRARR domain in DNA binding were analyzed by site-directed mutagenesis. DnaBMut1, with mutations R(328)A and R(329)A, had a significant decrease in the DNA dependence of ATPase activity and lost its DNA helicase activity completely, indicating the important roles of these residues in DNA binding and helicase activities. DnaBMut2, with mutations R(324)A and R(326)A, had significantly attenuated DNA binding as well as DNA-dependent ATPase and DNA helicase activities, indicating that these residues also play a role in DNA binding and helicase activities. The role(s) of the leucine zipper dimerization motif was (were) determined by deletion analysis. The DnaB Delta 1 mutant with a 55 amino acid C-terminal deletion, which left the leucine zipper and basic DNA binding regions intact, retained DNA binding as well as DNA helicase activities. However, the DnaB Delta 2 mutant with a 113 amino acid C-terminal deletion that included the leucine zipper dimerization motif, but not the RSRARR sequence, lost DNA binding, DNA helicase activities, and hexamer formation. The major findings of this study are (i) the leucine zipper dimerization domain, I(361)-L(389), is absolutely required for (a) dimerization and (b) ssDNA binding; (ii) the base-rich RSRARR sequence is required for DNA binding; (iii) three regions of domain gamma (gamma I, gamma II, and gamma III) differentially regulate the ATPase activity; (iv) there are likely three ssDNA binding sites per hexamer; and (v) a working model of DNA unwinding by the DnaB hexamer is proposed.     

The role of the C-terminal domain of protein tyrosine phosphatase-1B in phosphatase activity and substrate binding

Protein tyrosine phosphatase 1B (PTP-1B) has been implicated in the regulation of the insulin receptor. Dephosphorylation of the insulin receptor results in decreased insulin signaling and thus decreased glucose uptake. PTP-1B-/- mice have increased insulin sensitivity and are resistant to weight gain when fed a high fat diet, validating PTP-1B as a potential target for the treatment of type 2 diabetes. Many groups throughout the world have been searching for selective inhibitors for PTP-1B, and most of them target inhibitors to PTP-1B-(1-298), the N-terminal catalytic domain of the enzyme. However, the C-terminal domain is quite large and could influence the activity of the enzyme. Using two constructs of PTP-1B and a phosphopeptide as substrate, steady state assays showed that the presence of the C-terminal domain decreased both the Km and the k(cat) 2-fold. Pre-steady state kinetic experiments showed that the presence of the C-terminal domain improved the affinity of the enzyme for a phosphopeptide 2-fold, primarily because the off-rate was slower. This suggests that the C-terminal domain of PTP-1B may contact the phosphopeptide in some manner, allowing it to remain at the active site longer. This could be useful when screening libraries of compounds for inhibitors of PTP-1B. A compound that is able to make contacts with the C-terminal domain of PTP-1B would not only have a modest improvement in affinity but may also provide for specificity over other phosphatases.     

The helicase domain of phage P4 alpha protein overlaps the specific DNA binding domain.

Replication initiation depends on origin recognition, helicase, and primase activities. In phage P4, a second DNA region, the cis replication region (crr), is also required for replication initiation. The multifunctional alpha protein of phage P4, which is essential for DNA replication, combines the three aforementioned activities on a single polypeptide chain. Protein domains responsible for the activities were identified by mutagenesis. We show that mutations of residues G506 and K507 are defective in vivo in phage propagation and in unwinding of a forked helicase substrate. This finding indicates that the proposed P loop is essential for helicase activity. Truncations of gene product alpha (gp alpha) demonstrated that 142 residues of the C terminus are sufficient for specifically binding ori and crr DNA. The minimal binding domain retains gp alpha's ability to induce loop formation between ori and crr. In vitro and in vivo analysis of short C-terminal truncations indicate that the C terminus is needed for helicase activity as well as for specific DNA binding.     

Archaeal Hel308 domain V couples DNA binding to ATP hydrolysis and positions DNA for unwinding over the helicase ratchet

Hel308 and PolQ are paralogues with roles promoting genome stability in archaea and higher eukaryotes. The context in which they act is not clear, although Hel308 helicase from archaea may interact with abnormal replication forks. The atomic structure of archaeal Hel308 from Archaeoglobus fulgidus in complex with DNA was recently reported and has given insights into the mechanisms of superfamily-2 helicases generally. An intriguing aspect of the structure was the positioning of a C-terminal domain V relative to single-stranded DNA and to the helicase ratchet domain IV. We have mutagenised a triplet of arginine residues in domain V of archaeal Hel308 to assess the effects on DNA binding, unwinding, and ATPase activities. Our observations can now be interpreted in light of the atomic structure. We describe crucial roles for domain V as a brake on ATP hydrolysis by coupling it to binding single-stranded DNA and in positioning DNA relative to the helicase ratchet domain IV for efficient unwinding of forked DNA.     

Enzyme-catalyzed DNA unwinding. The role of ATP in helicase III activity

The enzyme helicase III catalyzes ATP-dependent unwinding of double-stranded DNA (Yarranto, G. T., Das, R. H., and Gefter, M. L. (1979) J. Biol. Chem. 254, 11997-12001). The free enzyme is able to bind to double- and single-stranded DNA. In the presence of ATP the enzyme can bind single- but not double-stranded DNA. The enzyme catalyzes an ADP-ATP exchange reaction in the absence of DNA. It is suggested that there is an enzyme.phosphate complex that discriminates between the two forms of DNA. These results are discussed in relation to a model that accounts for catalytic unwinding of DNA coupled to ATP hydrolysis.