Structural basis for DNA strand separation by a hexameric replicative helicase

Hexameric helicases are processive DNA unwinding machines but how they engage with a replication fork during unwinding is unknown. Using electron microscopy and single particle analysis we determined structures of the intact hexameric helicase E1 from papillomavirus and two complexes of E1 bound to a DNA replication fork end-labelled with protein tags. By labelling a DNA replication fork with streptavidin (dsDNA end) and Fab (5′ ssDNA) we located the positions of these labels on the helicase surface, showing that at least 10 bp of dsDNA enter the E1 helicase via a side tunnel. In the currently accepted ‘steric exclusion’ model for dsDNA unwinding, the active 3′ ssDNA strand is pulled through a central tunnel of the helicase motor domain as the dsDNA strands are wedged apart outside the protein assembly. Our structural observations together with nuclease footprinting assays indicate otherwise: strand separation is taking place inside E1 in a chamber above the helicase domain and the 5′ passive ssDNA strands exits the assembly through a separate tunnel opposite to the dsDNA entry point. Our data therefore suggest an alternative to the current general model for DNA unwinding by hexameric helicases.     

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.     

DnaB helicase activity is modulated by DNA geometry and force

The replicative helicase for Escherichia coli is DnaB, a hexameric, ring-shaped motor protein that encircles and translocates along ssDNA, unwinding dsDNA in advance of its motion. The microscopic mechanisms of DnaB are unknown; further, prior work has found that DnaB's activity is modified by other replication proteins, indicating some mechanistic flexibility. To investigate these issues, we quantified translocation and unwinding by single DnaB molecules in three tethered DNA geometries held under tension. Our data support the following conclusions: 1), Unwinding by DnaB is enhanced by force-induced destabilization of dsDNA. 2), The magnitude of this stimulation varies with the geometry of the tension applied to the DNA substrate, possibly due to interactions between the helicase and the occluded ssDNA strand. 3), DnaB unwinding and (to a lesser extent) translocation are interrupted by pauses, which are also dependent on force and DNA geometry. 4), DnaB moves slower when a large tension is applied to the helicase-bound strand, indicating that it must perform mechanical work to compact the strand against the applied force. Our results have implications for the molecular mechanisms of translocation and unwinding by DnaB and for the means of modulating DnaB activity.     

Dynamic coupling between the motors of DNA replication: hexameric helicase, DNA polymerase, and primase

Helicases are molecular motor proteins that couple NTP hydrolysis to directional movement along nucleic acids. A class of helicases characterized by their ring-shaped hexameric structures translocate processively and unidirectionally along single-stranded (ss) DNA to separate the strands of double-stranded (ds) DNA, aiding both in the initiation and fork progression during DNA replication. These replicative ring-shaped helicases are found from virus to human. We review recent biochemical and structural studies that have expanded our understanding on how hexameric helicases use the NTPase reaction to translocate on ssDNA, unwind dsDNA, and how their physical and functional interactions with the DNA polymerase and primase enzymes coordinate replication of the two strands of dsDNA.     

Dodecameric structure and ATPase activity of the human TIP48/TIP49 complex

TIP48 and TIP49 are two related and highly conserved eukaryotic AAA(+) proteins with an essential biological function and a critical role in major pathways that are closely linked to cancer. They are found together as components of several highly conserved chromatin-modifying complexes. Both proteins show sequence homology to bacterial RuvB but the nature and mechanism of their biochemical role remain unknown. Recombinant human TIP48 and TIP49 were assembled into a stable high molecular mass equimolar complex and tested for activity in vitro. TIP48/TIP49 complex formation resulted in synergistic increase in ATPase activity but ATP hydrolysis was not stimulated in the presence of single-stranded, double-stranded or four-way junction DNA and no DNA helicase or branch migration activity could be detected. Complexes with catalytic defects in either TIP48 or TIP49 had no ATPase activity showing that both proteins within the TIP48/TIP49 complex are required for ATP hydrolysis. The structure of the TIP48/TIP49 complex was examined by negative stain electron microscopy. Three-dimensional reconstruction at 20 A resolution revealed that the TIP48/TIP49 complex consisted of two stacked hexameric rings with C6 symmetry. The top and bottom rings showed substantial structural differences. Interestingly, TIP48 formed oligomers in the presence of adenine nucleotides, whilst TIP49 did not. The results point to biochemical differences between TIP48 and TIP49, which may explain the structural differences between the two hexameric rings and could be significant for specialised functions that the proteins perform individually.     

DNA Unwinding by Ring-Shaped T4 Helicase gp41 Is Hindered by Tension on the Occluded Strand

The replicative helicase for bacteriophage T4 is gp41, which is a ring-shaped hexameric motor protein that achieves unwinding of dsDNA by translocating along one strand of ssDNA while forcing the opposite strand to the outside of the ring. While much study has been dedicated to the mechanism of binding and translocation along the ssDNA strand encircled by ring-shaped helicases, relatively little is known about the nature of the interaction with the opposite, ‘occluded’ strand. Here, we investigate the interplay between the bacteriophage T4 helicase gp41 and the ss/dsDNA fork by measuring, at the single-molecule level, DNA unwinding events on stretched DNA tethers in multiple geometries. We find that gp41 activity is significantly dependent on the geometry and tension of the occluded strand, suggesting an interaction between gp41 and the occluded strand that stimulates the helicase. However, the geometry dependence of gp41 activity is the opposite of that found previously for the E. coli hexameric helicase DnaB. Namely, tension applied between the occluded strand and dsDNA stem inhibits unwinding activity by gp41, while tension pulling apart the two ssDNA tails does not hinder its activity. This implies a distinct variation in helicase-occluded strand interactions among superfamily IV helicases, and we propose a speculative model for this interaction that is consistent with both the data presented here on gp41 and the data that had been previously reported for DnaB.     

Mutations altering the interplay between GkDnaC helicase and DNA reveal an insight into helicase unwinding

Replicative helicases are essential molecular machines that utilize energy derived from NTP hydrolysis to move along nucleic acids and to unwind double-stranded DNA (dsDNA). Our earlier crystal structure of the hexameric helicase from Geobacillus kaustophilus HTA426 (GkDnaC) in complex with single-stranded DNA (ssDNA) suggested several key residues responsible for DNA binding that likely play a role in DNA translocation during the unwinding process. Here, we demonstrated that the unwinding activities of mutants with substitutions at these key residues in GkDnaC are 2-4-fold higher than that of wild-type protein. We also observed the faster unwinding velocities in these mutants using single-molecule experiments. A partial loss in the interaction of helicase with ssDNA leads to an enhancement in helicase efficiency, while their ATPase activities remain unchanged. In strong contrast, adding accessory proteins (DnaG or DnaI) to GkDnaC helicase alters the ATPase, unwinding efficiency and the unwinding velocity of the helicase. It suggests that the unwinding velocity of helicase could be modulated by two different pathways, the efficiency of ATP hydrolysis or protein-DNA interaction.     

Torsional regulation of hRPA-induced unwinding of double-stranded DNA

All cellular single-stranded (ss) DNA is rapidly bound and stabilized by single stranded DNA-binding proteins (SSBs). Replication protein A, the main eukaryotic SSB, is able to unwind double-stranded (ds) DNA by binding and stabilizing transiently forming bubbles of ssDNA. Here, we study the dynamics of human RPA (hRPA) activity on topologically constrained dsDNA with single-molecule magnetic tweezers. We find that the hRPA unwinding rate is exponentially dependent on torsion present in the DNA. The unwinding reaction is self-limiting, ultimately removing the driving torsional stress. The process can easily be reverted: release of tension or the application of a rewinding torque leads to protein dissociation and helix rewinding. Based on the force and salt dependence of the in vitro kinetics we anticipate that the unwinding reaction occurs frequently in vivo. We propose that the hRPA unwinding reaction serves to protect and stabilize the dsDNA when it is structurally destabilized by mechanical stresses.     

Mcm4,6,7 uses a "pump in ring" mechanism to unwind DNA by steric exclusion and actively translocate along a duplex

Mcm4,6,7 is a ring-shaped heterohexamer and the putative eukaryotic replication fork helicase. In this study, we examine the mechanism of Mcm4,6,7. Mcm4,6,7 binds to only one strand of a duplex during unwinding, corresponding to the leading strand of a replication fork. Mcm4,6,7 unwinding stops at a nick in either strand. The Mcm4,6,7 ring also actively translocates along duplex DNA, enabling the protein to drive branch migration of Holliday junctions. The Mcm4,6,7 mechanism is very similar to DnaB, except the proteins translocate with opposite polarity along DNA. Mcm4,6,7 and DnaB have different structural folds and evolved independently; thus, the similarity in mechanism is surprising. We propose a "pump in ring" mechanism for both Mcm4,6,7 and DnaB, wherein a single-stranded DNA pump is situated within the central channel of the ring-shaped helicase, and unwinding is the result of steric exclusion. In this example of convergent evolution, the "pump in ring" mechanism was probably selected by eukaryotic and bacterial replication fork helicases in order to restrict unwinding to replication fork structures, stop unwinding when the replication fork encounters a nick, and actively translocate along duplex DNA to accomplish additional activities such as DNA branch migration.     

Genotype-specific differences in structural features of hepatitis C virus (HCV) p7 membrane protein

The 63 amino acid polytopic membrane protein, p7, encoded by hepatitis C virus (HCV) is involved in the modulation of electrochemical gradients across membranes within infected cells. Structural information relating to p7 from multiple genotypes has been generated in silico (e.g. genotype (GT) 1a), as well as obtained from experiments in form of monomeric and hexameric structures (GTs 1b and 5a, respectively). However, sequence diversity and structural differences mean that comparison of their channel gating behaviour has not thus far been simulated. Here, a molecular model of the monomeric GT 1a protein is optimized and assembled into a hexameric bundle for comparison with both the 5a hexamer structure and another hexameric bundle generated using the GT 1b monomer structure. All bundles tend to turn into a compact structure during molecular dynamics (MD) simulations (Gromos96 (ffG45a3)) in hydrated lipid bilayers, as well as when simulated at ‘low pH’, which may trigger channel opening according to some functional studies. Both GT 1a and 1b channel models are gated via movement of the parallel aligned helices, yet the scenario for the GT 5a protein is more complex, with a short N-terminal helix being involved. However, all bundles display pulsatile dynamics identified by monitoring water dynamics within the pore.     

Adjacent residues in the E1 initiator beta-hairpin define different roles of the beta-hairpin in Ori melting, helicase loading, and helicase activity

We have analyzed two residues in the helicase domain of the E1 initiator protein. These residues are part of a highly conserved structural motif, the beta-hairpin, which is present in the helicase domain of all papovavirus initiator proteins. These proteins are unique in their ability to transition from local template melting activity to unwinding. We demonstrate that the beta-hairpin has two functions. First, it is the tool used by the E1 double trimer (DT) to pry open and melt double-stranded DNA. Second, it is required for the unwinding activity of the hexameric E1 helicase. The fact that the same structural element, but not the same residues, contacts both dsDNA in the DT for melting and ssDNA in the double hexamer (DH) for helicase activity provides a link between local origin melting and DNA helicase activity and suggests how the transition between these two states comes about.     

Single-molecule studies reveal dynamics of DNA unwinding by the ring-shaped T7 helicase

Helicases are molecular motors that separate DNA strands for efficient replication of genomes. We probed the kinetics of individual ring-shaped T7 helicase molecules as they unwound double-stranded DNA (dsDNA) or translocated on single-stranded DNA (ssDNA). A distinctive DNA sequence dependence was observed in the unwinding rate that correlated with the local DNA unzipping energy landscape. The unwinding rate increased approximately 10-fold (approaching the ssDNA translocation rate) when a destabilizing force on the DNA fork junction was increased from 5 to 11 pN. These observations reveal a fundamental difference between the mechanisms of ring-shaped and nonring-shaped helicases. The observed force-velocity and sequence dependence are not consistent with a simple passive unwinding model. However, an active unwinding model fully supports the data even though the helicase on its own does not unwind at its optimal rate. This work offers insights into possible ways helicase activity is enhanced by associated proteins.     

Common determinants in DNA melting and helicase-catalysed DNA unwinding by papillomavirus replication protein E1

E1 and T-antigen of the tumour viruses bovine papillomavirus (BPV-1) and Simian virus 40 (SV40) are the initiator proteins that recognize and melt their respective origins of replication in the initial phase of DNA replication. These proteins then assemble into processive hexameric helicases upon the single-stranded DNA that they create. In T-antigen, a characteristic loop and hairpin structure (the pre-sensor 1β hairpin, PS1βH) project into a central cavity generated by protein hexamerization. This channel undergoes large ATP-dependent conformational changes, and the loop/PS1βH is proposed to form a DNA binding site critical for helicase activity. Here, we show that conserved residues in BPV E1 that probably form a similar loop/hairpin structure are required for helicase activity and also origin (ori) DNA melting. We propose that DNA melting requires the cooperation of the E1 helicase domain (E1HD) and the origin binding domain (OBD) tethered to DNA. One possible mechanism is that with the DNA locked in the loop/PS1βH DNA binding site, ATP-dependent conformational changes draw the DNA inwards in a twisting motion to promote unwinding.     

Molecular architecture of the recombinant human MCM2-7 helicase in complex with nucleotides and DNA

DNA replication is a key biological process that involves different protein complexes whose assembly is rigorously regulated in a successive order. One of these complexes is a replicative hexameric helicase, the MCM complex, which is essential for the initiation and elongation phases of replication. After the assembly of a double heterohexameric MCM2-7 complex at replication origins in G1, the 2 heterohexamers separate from each other and associate with Cdc45 and GINS proteins in a CMG complex that is capable of unwinding dsDNA during S phase. Here, we have reconstituted and characterized the purified human MCM2-7 (hMCM2-7) hexameric complex by co-expression of its 6 different subunits in insect cells. The conformational variability of the complex has been analyzed by single particle electron microscopy in the presence of different nucleotide analogs and DNA. The interaction with nucleotide stabilizes the complex while DNA introduces conformational changes in the hexamer inducing a cylindrical shape. Our studies suggest that the assembly of GINS and Cdc45 to the hMCM2-7 hexamer would favor conformational changes on the hexamer bound to ssDNA shifting the cylindrical shape of the complex into a right-handed spiral conformation as observed in the CMG complex bound to DNA.     

Unzipping mechanism of the double-stranded DNA unwinding by a hexameric helicase: the effect of the 3' arm and the stability of the dsDNA on the unwinding activity of the Escherichia coli DnaB helicase

The effect of two structural elements of a replication DNA fork substrate, the length of the 3' arm of the fork and the stability of the double-stranded DNA (dsDNA) part, on the kinetics of the dsDNA unwinding by the Escherichia coli hexameric helicase DnaB protein has been examined under single turnover conditions using the rapid quench-flow technique. The length of the 3' arm of the replication fork, i.e. the number of nucleotides in the arm, is a major structural factor that controls the unwinding rate and processivity of the helicase. The data show the existence of an optimal length of the 3' arm where there is the highest unwinding rate and processivity, indicating that during the unwinding process, the helicase transiently interacts with the 3' arm at a specific distance on the arm with respect to the duplex part of the DNA. Moreover, the area on the enzyme that engages in interactions has also a discrete size. For DNA substrates with the 3' arm containing 14, or less, nucleotide residues, the DnaB helicase becomes a completely distributive enzyme. However, the 3' arm is not a "specific activating cofactor" in the unwinding reaction. Rather, the 3' arm plays a role as a mechanical fulcrum for the enzyme, necessary to provide support for the advancing large helicase molecule on the opposite strand of the DNA. Binding of ATP is necessary to engage the 3' arm with the DnaB helicase, but it does not change the initial distribution of complexes of the enzyme with the DNA fork substrate. Stability of the dsDNA has a significant effect on the unwinding rate and processivity. The unwinding rate constant is a decreasing linear function of the fractional content of GC base-pairs in the dsDNA, indicating that the activation of the unwinding step is proportional to the stability of the nucleic acid.     

Replication protein A interactions with DNA. 2. Characterization of double-stranded DNA-binding/helix-destabilization activities and the role of the zinc-finger domain in DNA interactions

Human replication protein A (RPA) is a heterotrimeric single-stranded DNA-binding protein that is composed of subunits of 70, 32, and 14 kDa. RPA is required for multiple processes in cellular DNA metabolism. RPA has been reported to (1) bind with high affinity to single-stranded DNA (ssDNA), (2) bind specifically to certain double-stranded DNA (dsDNA) sequences, and (3) have DNA helix-destabilizing ("unwinding") activity. We have characterized both dsDNA binding and helix destabilization. The affinity of RPA for dsDNA was lower than that of ssDNA and precisely correlated with the melting temperature of the DNA fragment. The rates of helix destabilization and dsDNA binding were similar, and both were slow relative to the rate of binding ssDNA. We have previously mapped the regions required for ssDNA binding [Walther et al. (1999) Biochemistry 38, 3963-3973]. Here, we show that both helix-destabilization and dsDNA-binding activities map to the central DNA-binding domain of the 70-kDa subunit and that other domains of RPA are needed for optimal activity. We conclude that all types of RPA binding are manifestations of RPA ssDNA-binding activity and that dsDNA binding occurs when RPA destabilizes a region of dsDNA and binds to the resulting ssDNA. The 70-kDa subunit of all RPA homologues contains a highly conserved putative (C-X2-C-X13-C-X2-C) zinc finger. This motif directly interacts with DNA and contributes to dsDNA-binding/unwinding activity. Evidence is presented that a metal ion is required for the function of the zinc-finger motif.     

Dynamic mechanism of nick recognition by DNA ligase.

DNA ligases are the enzymes responsible for the repair of single-stranded and double-stranded nicks in dsDNA. DNA ligases are structurally similar, possibly sharing a common molecular mechanism of nick recognition and ligation catalysis. This mechanism remains unclear, in part because the structure of ligase in complex with dsDNA has yet to be solved. DNA ligases share common structural elements with DNA polymerases, which have been cocrystallized with dsDNA. Based on the observed DNA polymerase-dsDNA interactions, we propose a mechanism for recognition of a single-stranded nick by DNA ligase. According to this mechanism, ligase induces a B-to-A DNA helix transition of the enzyme-bound dsDNA motif, which results in DNA contraction, bending and unwinding. For non-nicked dsDNA, this transition is reversible, leading to dissociation of the enzyme. For a nicked dsDNA substrate, the contraction of the enzyme-bound DNA motif (a) triggers an opened-closed conformational change of the enzyme, and (b) forces the motif to accommodate the strained A/B-form hybrid conformation, in which the nicked strand tends to retain a B-type helix, while the non-nicked strand tends to form a shortened A-type helix. We propose that this conformation is the catalytically competent transition state, which leads to the formation of the DNA-AMP intermediate and to the subsequent sealing of the nick.     

Translocation and Stability of Replicative DNA Helicases upon Encountering DNA-Protein Cross-links

DNA-protein cross-links (DPCs) are formed when cells are exposed to various DNA-damaging agents. Because DPCs are extremely large, steric hindrance conferred by DPCs is likely to affect many aspects of DNA transactions. In DNA replication, DPCs are first encountered by the replicative helicase that moves at the head of the replisome. However, little is known about how replicative helicases respond to covalently immobilized protein roadblocks. In the present study we elucidated the effect of DPCs on the DNA unwinding reaction of hexameric replicative helicases in vitro using defined DPC substrates. DPCs on the translocating strand but not on the nontranslocating strand impeded the progression of the helicases including the phage T7 gene 4 protein, simian virus 40 large T antigen, Escherichia coli DnaB protein, and human minichromosome maintenance Mcm467 subcomplex. The impediment varied with the size of the cross-linked proteins, with a threshold size for clearance of 5.0–14.1 kDa. These results indicate that the central channel of the dynamically translocating hexameric ring helicases can accommodate only small proteins and that all of the helicases tested use the steric exclusion mechanism to unwind duplex DNA. These results further suggest that DPCs on the translocating and nontranslocating strands constitute helicase and polymerase blocks, respectively. The helicases stalled by DPC had limited stability and dissociated from DNA with a half-life of 15–36 min. The implications of the results are discussed in relation to the distinct stabilities of replisomes that encounter tight but reversible DNA-protein complexes and irreversible DPC roadblocks.