Coupling of DNA binding and helicase activity is mediated by a conserved loop in the MCM protein

Minichromosome maintenance (MCM) helicases are the presumptive replicative helicases, thought to separate the two strands of chromosomal DNA during replication. In archaea, the catalytic activity resides within the C-terminal region of the MCM protein. In Methanothermobacter thermautotrophicus the N-terminal portion of the protein was shown to be involved in protein multimerization and binding to single and double stranded DNA. MCM homologues from many archaeal species have highly conserved predicted amino acid similarity in a loop located between β7 and β8 in the N-terminal part of the molecule. This high degree of conservation suggests a functional role for the loop. Mutational analysis and biochemical characterization of the conserved residues suggest that the loop participates in communication between the N-terminal portion of the helicase and the C-terminal catalytic domain. Since similar residues are also conserved in the eukaryotic MCM proteins, the data presented here suggest a similar coupling between the N-terminal and catalytic domain of the eukaryotic enzyme.     

Human RECQ5beta, a protein with DNA helicase and strand-annealing activities in a single polypeptide

Proteins belonging to the highly conserved RecQ helicase family are essential for the maintenance of genomic stability. Here, we describe the biochemical properties of the human RECQ5beta protein. Like BLM and WRN, RECQ5beta is an ATP-dependent 3'-5' DNA helicase that can promote migration of Holliday junctions. However, RECQ5beta required the single-stranded DNA-binding protein RPA in order to mediate the efficient unwinding of oligonucleotide-based substrates. Surprisingly, we found that RECQ5beta possesses an intrinsic DNA strand-annealing activity that is inhibited by RPA. Analysis of deletion variants of RECQ5beta revealed that the DNA helicase activity resides in the conserved N-terminal portion of the protein, whereas strand annealing is mediated by the unique C-terminal domain. Moreover, the strand-annealing activity of RECQ5beta was strongly inhibited by ATPgammaS, a poorly hydrolyzable analog of ATP. This effect was alleviated by mutations in the ATP-binding motif of RECQ5beta, indicating that the ATP-bound form of the protein cannot promote strand annealing. This is the first demonstration of a DNA helicase with an intrinsic DNA strand-annealing function residing in a separate domain.     

Stimulation of MCM helicase activity by a Cdc6 protein in the archaeon Thermoplasma acidophilum

Replicative DNA helicases are ring-shaped hexamers that play an essential role in chromosomal DNA replication. They unwind the two strands of the duplex DNA and provide the single-stranded (ss) DNA substrate for the polymerase. The minichromosome maintenance (MCM) proteins are thought to function as the replicative helicases in eukarya and archaea. The proteins of only a few archaeal organisms have been studied and revealed that although all have similar amino acid sequences and overall structures they differ in their biochemical properties. In this report the biochemical properties of the MCM protein from the archaeon Thermoplasma acidophilum is described. The enzyme has weak helicase activity on a substrate containing only a 3′-ssDNA overhang region and the protein requires a forked DNA structure for efficient helicase activity. It was also found that the helicase activity is stimulated by one of the two T.acidophilum Cdc6 homologues. This is an interesting observation as it is in sharp contrast to observations made with MCM and Cdc6 homologues from other archaea in which the helicase activity is inhibited when bound to Cdc6.     

Mutational analysis of conserved aspartic acid residues in the <Emphasis Type="Italic">Methanothermobacter thermautotrophicus</Emphasis> MCM helicase

Minichromosome maintenance (MCM) helicases are thought to function as the replicative helicases in archaea and eukarya, unwinding the duplex DNA in the front of the replication fork. The archaeal MCM helicase can be divided into three parts, the N-terminal, catalytic, and C-terminal regions. The N-terminal part of the protein is divided into three domains, A, B, and C, and was shown to be involved in protein multimerization and binding to single- and double-stranded DNA. Two Asp residues found in domain C are conserved among MCM proteins from different archaea. These residues are located in a loop at the interface with domain A. Mutations of these residues in the Methanothermobacter thermautotrophicus MCM protein, Asp202 and Asp203, to Asn result in a significant reduction in the ability of the enzyme to bind DNA and in lower thermal stability. However, the mutant proteins retained helicase and ATPase activities. Further investigation of the DNA binding revealed that the presence of ATP rescues the DNA binding deficiencies by these mutant proteins. Possible roles of these conserved residues in MCM function are discussed.     

The zinc finger domain of the archaeal minichromosome maintenance protein is required for helicase activity

The minichromosome maintenance (MCM) proteins, a family of six conserved polypeptides found in all eukaryotes, are essential for DNA replication. The archaeon Methanobacterium thermoautotrophicum Delta H contains a single homologue of MCM with biochemical properties similar to those of the eukaryotic enzyme. The amino acid sequence of the archaeal protein contains a putative zinc-binding domain of the CX(2)CX(n)CX(2)C (C(4)) type. In this study, the roles of the zinc finger domain in MCM function were examined using recombinant wild-type and mutant proteins expressed and purified from Escherichia coli. The protein with a mutation in the zinc motif forms a dodecameric complex similar to the wild-type enzyme. The mutant enzyme, however, is impaired in DNA-dependent ATPase activity and single-stranded DNA binding, and it does not possess helicase activity. These results illustrate the importance of the zinc-binding domain for archaeal MCM function and suggest a role for zinc binding in the eukaryotic MCM complex as well, since four out of the six eukaryotic MCM proteins contain a similar zinc-binding motif.     

Modular organization of the Sulfolobus solfataricus mini-chromosome maintenance protein

Mini-chromosome maintenance (MCM) proteins form ring-like hexameric complexes that are commonly believed to act as the replicative DNA helicase at the eukaryotic/archaeal DNA replication fork. Because of their simplified composition with respect to the eukaryotic counterparts, the archaeal MCM complexes represent a good model system to use in analyzing the structural/functional relationships of these important replication factors. In this study the domain organization of the MCM-like protein from Sulfolobus solfataricus (Sso MCM) has been dissected by trypsin partial proteolysis. Three truncated derivatives of Sso MCM corresponding to protease-resistant domains were produced as soluble recombinant proteins and purified: the N-terminal domain (N-ter, residues 1-268); a fragment comprising the AAA+ and C-terminal domains (AAA+-C-ter, residues 269-686); and the C-terminal domain (C-ter, residues 504-686). All of the purified recombinant proteins behaved as monomers in solution as determined by analytical gel filtration chromatography, suggesting that the polypeptide chain integrity is required for stable oligomerization of Sso MCM. However, the AAA+-C-ter derivative, which includes the AAA+ motor domain and retains ATPase activity, was able to form dimers in solution when ATP was present, as analyzed by size exclusion chromatography and glycerol gradient sedimentation analyses. Interestingly, the AAA+-C-ter protein could displace oligonucleotides annealed to M13 single-stranded DNA although with a reduced efficiency in comparison with the full-sized Sso MCM. The implications of these findings for understanding the DNA helicase mechanism of the MCM complex are discussed.     

Multiple Enzymatic Activities Associated with Recombinant NS3 Protein of Hepatitis C Virus

The hepatitis C virus (HCV) nonstructural 3 protein (NS3) contains at least two domains associated with multiple enzymatic activities; a serine protease activity resides in the N-terminal one-third of the protein, whereas RNA helicase activity and RNA-stimulated nucleoside triphosphatase activity are associated with the C-terminal portion. To study the possible mutual influence of these enzymatic activities, a full-length NS3 polypeptide of 67 kDa was expressed as a nonfusion protein in Escherichia coli, purified to homogeneity, and shown to retain all three enzymatic activities. The protease activity of the full-length NS3 was strongly dependent on the activation by a synthetic peptide spanning the central hydrophobic core of the NS4A cofactor. Once complexed with the NS4A-derived peptide, the full-length NS3 protein and the isolated N-terminal protease domain cleaved synthetic peptide substrates with comparable efficiency. We show that, as in the case of the isolated protease domain, the protease activity of full-length NS3 undergoes inhibition by the N-terminal cleavage products of substrate peptides corresponding to the NS4A-NS4B and NS5A-NS5B. We have also characterized and quantified the NS3 ATPase, RNA helicase, and RNA-binding activities under optimized reaction conditions. Compared with the isolated N-terminal and C-terminal domains, recombinant full-length NS3 did not show significant differences in the three enzymatic activities analyzed in independent in vitro assays. We have further explored the possible interdependence of the NS3 N-terminal and C-terminal domains by analyzing the effect of polynucleotides on the modulation of all NS3 enzymatic functions. Our results demonstrated that the observed inhibition of the NS3 proteolytic activity by single-stranded RNA is mediated by direct interaction with the protease domain rather than with the helicase RNA-binding domain.     

Unwinding the structure and function of the archaeal MCM helicase

During chromosomal DNA replication, the replicative helicase unwinds the duplex DNA to provide the single-stranded DNA substrate for the polymerase. In archaea, the replicative helicase is the minichromosome maintenance (MCM) complex. The enzyme utilizes the energy of ATP hydrolysis to translocate along one strand of the duplex and unwind the complementary strand. Much progress has been made in elucidating structure and function since the first report on the biochemical properties of an archaeal MCM protein in 1999. We now know the biochemical and structural properties of the enzyme from several archaeal species and some of the mechanisms by which the enzyme is regulated. This review summarizes recent studies on the archaeal MCM protein and discusses the implications for helicase function and DNA replication in archaea.     

Chemical shift assignments for F-plasmid TraI (381–569)

TraI, the F plasmid-encoded nickase, is a 1,756 amino acid protein essential for conjugative transfer of F plasmid DNA from one bacterium to another. While crystal structures of N- and C-terminal domains of F TraI have been determined, central domains of the protein are structurally unexplored. These middle domains (between residues 306 and 1,500) are known to both bind single-stranded DNA (ssDNA) and unwind DNA through a highly processive helicase activity. Of this central region, the more C-terminal portion (~900–1500) appears related to helicase RecD of the E. coli RecBCD complex. The more N-terminal portion (306–900), however, shows limited sequence similarity to other proteins. In an attempt to define the structure of well-folded domains of this middle region and discern their function, we have isolated stable regions of TraI following limited proteolysis. One of these regions, TraI (381–569), was identified and a genetic construct encoding it was engineered. The protein was expressed, purified, and the sequence-specific chemical shifts for it were assigned.     

Solution structure and small angle scattering analysis of TraI (381-569)

TraI, the F plasmid-encoded nickase, is a 1756 amino acid protein essential for conjugative transfer of plasmid DNA from one bacterium to another. Although crystal structures of N- and C-terminal domains of F TraI have been determined, central domains of the protein are structurally unexplored. The central region (between residues 306 and 1520) is known to both bind single-stranded DNA (ssDNA) and unwind DNA through a highly processive helicase activity. Here, we show that the ssDNA binding site is located between residues 381 and 858, and we also present the high-resolution solution structure of the N-terminus of this region (residues 381-569). This fragment folds into a four-strand parallel β sheet surrounded by α helices, and it resembles the structure of the N-terminus of helicases such as RecD and RecQ despite little sequence similarity. The structure supports the model that F TraI resulted from duplication of a RecD-like domain and subsequent specialization of domains into the more N-terminal ssDNA binding domain and the more C-terminal domain containing helicase motifs. In addition, we provide evidence that the nickase and ssDNA binding domains of TraI are held close together by an 80-residue linker sequence that connects the two domains. These results suggest a possible physical explanation for the apparent negative cooperativity between the nickase and ssDNA binding domain.     

Delineation of the high-affinity single-stranded telomeric DNA-binding domain of Saccharomyces cerevisiae Cdc13

Cdc13 is an essential protein from Saccharomyces cerevisiae that caps telomeres by protecting the C-rich telomeric DNA strand from degradation and facilitates telomeric DNA replication by telomerase. In vitro, Cdc13 binds TG-rich single-stranded telomeric DNA with high affinity and specificity. A previously identified domain of Cdc13 encompassing amino acids 451–694 (the 451–694 DBD) retains the single-stranded DNA-binding properties of the full-length protein; however, this domain contains a large unfolded region identified in heteronuclear NMR experiments. Trypsin digestion and MALDI mass spectrometry were used to identify the minimal DNA-binding domain (the 497–694 DBD) necessary and sufficient for full DNA-binding activity. This domain was completely folded, and the N-terminal unfolded region removed was shown to be dispensable for function. Using affinity photocrosslinking to site-specifically modified telomeric single-stranded DNA, the 497–694 DBD was shown to contact the entire 11mer required for high-affinity binding. Intriguingly, both domains bound single-stranded telomeric DNA with much greater affinity than the full-length protein. The full-length protein exhibited the same rate of dissociation as both domains, however, indicating that the full-length protein contains a region that inhibits association with single-stranded telomeric DNA.     

Interactions between the archaeal Cdc6 and MCM proteins modulate their biochemical properties

The origin recognition complex, Cdc6 and the minichromosome maintenance (MCM) complex play essential roles in the initiation of eukaryotic DNA replication. Homologs of these proteins may play similar roles in archaeal replication initiation. While the interactions among the eukaryotic initiation proteins are well documented, the protein–protein interactions between the archaeal proteins have not yet been determined. Here, an extensive structural and functional analysis of the interactions between the Methanothermobacter thermautotrophicus MCM and the two Cdc6 proteins (Cdc6-1 and -2) identified in the organism is described. The main contact between Cdc6 and MCM occurs via the N-terminal portion of the MCM protein. It was found that Cdc6–MCM interaction, but not Cdc6–DNA binding, plays the predominant role in regulating MCM helicase activity. In addition, the data showed that the interactions with MCM modulate the autophosphorylation of Cdc6-1 and -2. The results also suggest that MCM and DNA may compete for Cdc6-1 protein binding. The implications of these observations for the initiation of archaeal DNA replication are discussed.     

Modular architecture of the hexameric human mitochondrial DNA helicase

We have probed the structure of the human mitochondrial DNA helicase, an enzyme that uses the energy of nucleotide hydrolysis to unwind duplex DNA during mitochondrial DNA replication. This novel helicase shares substantial amino acid sequence and functional similarities with the bacteriophage T7 primase-helicase. We show in velocity sedimentation and gel filtration analyses that the mitochondrial DNA helicase exists as a hexamer. Limited proteolysis by trypsin results in the production of several stable fragments, and N-terminal sequencing reveals distinct N and C-terminal polypeptides that represent minimal structural domains. Physical analysis of the proteolytic products defines the region required to maintain oligomeric structure to reside within amino acid residues approximately 405-590. Truncations of the N and C termini affect differentially DNA-dependent ATPase activity, and whereas a C-terminal domain polypeptide is functional, an N-terminal domain polypeptide lacks ATPase activity. Sequence similarity and secondary structural alignments combined with biochemical data suggest that amino acid residue R609 serves as the putative arginine finger that is essential for ATPase activity in ring helicases. The hexameric conformation and modular architecture revealed in our study document that the mitochondrial DNA helicase and bacteriophage T7 primase-helicase share physical features. Our findings place the mitochondrial DNA helicase firmly in the DnaB-like family of replicative DNA helicases.     

Steric exclusion and wrapping of the excluded DNA strand occurs along discrete external binding paths during MCM helicase unwinding

The minichromosome maintenance (MCM) helicase complex is essential for the initiation and elongation of DNA replication in both the eukaryotic and archaeal domains. The archaeal homohexameric MCM helicase from Sulfolobus solfataricus serves as a model for understanding mechanisms of DNA unwinding. In this report, the displaced 5'-tail is shown to provide stability to the MCM complex on DNA and contribute to unwinding. Mutations in a positively charged patch on the exterior surface of the MCM hexamer destabilize this interaction, alter the path of the displaced 5'-tail DNA and reduce unwinding. DNA footprinting and single-molecule fluorescence experiments support a previously unrecognized wrapping of the 5'-tail. This mode of hexameric helicase DNA unwinding is termed the steric exclusion and wrapping (SEW) model, where the 3'-tail is encircled by the helicase while the displaced 5'-tail wraps around defined paths on the exterior of the helicase. The novel wrapping mechanism stabilizes the MCM complex in a positive unwinding mode, protects the displaced single-stranded DNA tail and prevents reannealing.     

Substrate requirements for duplex DNA translocation by the eukaryal and archaeal minichromosome maintenance helicases

Replicative DNA helicases are ring-shaped hexamers that play an essential role in DNA synthesis by separating the two strands of chromosomal DNA to provide the single-stranded (ss) substrate for replicative polymerases. Biochemical and structural studies suggest that these helicases translocate along one strand of the duplex, which passes through and interacts with the central channel of these ring-shaped hexamers, and displace the complementary strand. A number of these helicases were shown to also encircle both strands simultaneously and then translocate along double-stranded (ds)DNA. In this report it is shown that the Schizosaccharomyces pombe Mcm4,6,7 complex and archaeal minichromosome maintenance (MCM) helicase from Methanothermobacter thermautotrophicus move along duplex DNA. These two helicases, however, differ in the substrate required to support dsDNA translocation. Although the S. pombe Mcm4,6,7 complex required a 3'-overhang ssDNA region to initiate its association with the duplex, the archaeal protein initiated its transit along dsDNA in the absence of a 3'-overhang region, as well. Furthermore, DNA substrates containing a streptavidin-biotin steric block inhibited the movement of the eukaryotic helicase along ss and dsDNAs but not of the archaeal enzyme. The M. thermautotrophicus MCM helicase, however, was shown to displace a streptavidin-biotin complex from ss, as well as dsDNAs. The possible roles of dsDNA translocation by the MCM proteins during the initiation and elongation phases of chromosomal replication are discussed.     

The domain structure of Helicobacter pylori DnaB helicase: the N-terminal domain can be dispensable for helicase activity whereas the extreme C-terminal region is essential for its function

Hexameric DnaB type replicative helicases are essential for DNA strand unwinding along with the direction of replication fork movement. These helicases in general contain an amino terminal domain and a carboxy terminal domain separated by a linker region. Due to the lack of crystal structure of a full-length DnaB like helicase, the domain structure and function of these types of helicases are not clear. We have reported recently that Helicobacter pylori DnaB helicase is a replicative helicase in vitro and it can bypass Escherichia coli DnaC activity in vivo. Using biochemical, biophysical and genetic complementation assays, here we show that though the N-terminal region of HpDnaB is required for conformational changes between C6 and C3 rotational symmetry, it is not essential for in vitro helicase activity and in vivo function of the protein. Instead, an extreme carboxy terminal region and an adjacent unique 34 amino acid insertion region were found to be essential for HpDnaB activity suggesting that these regions are important for proper folding and oligomerization of this protein. These results confer great potential in understanding the domain structures of DnaB type helicases and their related function.     

Cooperation of the N-terminal Helicase and C-terminal endonuclease activities of Archaeal Hef protein in processing stalled replication forks

Blockage of replication fork progression often occurs during DNA replication, and repairing and restarting stalled replication forks are essential events in all organisms for the maintenance of genome integrity. The repair system employs processing enzymes to restore the stalled fork. In Archaea Hef is a well conserved protein that specifically cleaves nicked, flapped, and fork-structured DNAs. This enzyme contains two distinct domains that are similar to the DEAH helicase family and XPF nuclease superfamily proteins. Analyses of truncated mutant proteins consisting of each domain revealed that the C-terminal nuclease domain independently recognized and incised fork-structured DNA. The N-terminal helicase domain also specifically unwound fork-structured DNA and Holliday junction DNA in the presence of ATP. Moreover, the endonuclease activity of the whole Hef protein was clearly stimulated by ATP hydrolysis catalyzed by the N-terminal domain. These enzymatic properties suggest that Hef efficiently resolves stalled replication forks by two steps, which are branch point transfer to the 5'-end of the nascent lagging strand by the N-terminal helicase followed by template strand incision for leading strand synthesis by the C-terminal endonuclease.     

Biochemical analysis of human PIF1 helicase and functions of its N-terminal domain

The evolutionary conserved PIF1 DNA helicase family appears to have largely nonoverlapping cellular functions. To better understand the functions of human PIF1, we investigated biochemical properties of this protein. Analysis of single-stranded (ss) DNA-dependent ATPase activity revealed nonstructural ssDNA to greatly stimulate ATPase activity due to a high affinity for PIF1, even though PIF1 preferentially unwinds forked substrates. This suggests that PIF1 needs a ssDNA region for loading and a forked structure for translocation entrance into a double strand region. Deletion analysis demonstrated novel functions of a unique N-terminal portion, named the PIF1 N-terminal (PINT) domain. When the PINT domain was truncated, apparent affinity for ssDNA and unwinding activity were much reduced, even though the maximum velocity of ATPase activity and K_m value for ATP were not affected. We suggest that the PINT domain contributes to enhancing the interaction with ssDNA through intrinsic binding activity. In addition, we found DNA strand-annealing activity, also residing in the PINT domain. Notably, the unwinding and annealing activities were inhibited by replication protein A. These results suggest that the functions of PIF1 might be restricted with particular situations and DNA structures.     

DNA binding of PriA protein requires cooperation of the N-terminal D-loop/arrested-fork binding and C-terminal helicase domains

PriA protein is essential for RecA-dependent DNA replication induced by stalled replication forks in Escherichia coli. PriA is a DEXH-type DNA helicase, ATPase activity of which depends on its binding to structured DNA including a D-loop-like structure. Here, we show that the N-terminal 181-amino acid polypeptide can form a complex with D-loop in gel shift assays and have identified a unique motif present in the N-terminal segment of PriA that plays a role in its DNA binding. We have also identified residues in the C terminus proximal helicase domain essential for D-loop binding. PriA proteins mutated in this domain do not bind to D-loop, despite the presence of the N-terminal DNA-binding motif. Those mutants that cannot bind to D-loop in vitro do not support a recombination-dependent mode of DNA replication in vivo, indicating that binding to a D-loop-like structure is essential for the ability of PriA to initiate DNA replication and repair from stalled replication forks. We propose that binding of the PriA protein to stalled replication forks requires proper configuration of the N-terminal fork-recognition and C-terminal helicase domains and that the latter may stabilize binding and increase binding specificity.