Fluorescent single-stranded DNA binding protein as a probe for sensitive, real-time assays of helicase activity

The formation and maintenance of single-stranded DNA (ssDNA) are essential parts of many processes involving DNA. For example, strand separation of double-stranded DNA (dsDNA) is catalyzed by helicases, and this exposure of the bases on the DNA allows further processing, such as replication, recombination, or repair. Assays of helicase activity and probes for their mechanism are essential for understanding related biological processes. Here we describe the development and use of a fluorescent probe to measure ssDNA formation specifically and in real time, with high sensitivity and time resolution. The reagentless biosensor is based on the ssDNA binding protein (SSB) from Escherichia coli, labeled at a specific site with a coumarin fluorophore. Its use in the study of DNA manipulations involving ssDNA intermediates is demonstrated in assays for DNA unwinding, catalyzed by DNA helicases.     

Selective breeding as a tool to probe skeletal response to high voluntary locomotor activity in mice

We present a novel mouse-model for the study of skeletal structureand evolution, based on selective breeding for high levels ofvoluntary wheel running. Whereas traditional models (originallyinbred strains, more recently knockouts and transgenics) relyon the study of mutant or laboratory-manipulated phenotypes,we have studied changes in skeletal morphometrics resultingfrom many generations of artificial selection for high activityin the form of wheel running, in which mice engage voluntarily.Mice from the four replicate High Runner (HR) lines run nearlythree times as many revolutions during days 5 and 6 of a 6-dayexposure to wheels (1.12 m circumference). We have found significantchanges in skeletal dimensions of the hind limbs, includingdecreased directional asymmetry, larger femoral heads, and widerdistal femora. The latter two have been hypothesized as evolutionaryadaptations for long-distance locomotion in hominids. Exercise-trainingstudies involving experimental groups with and without accessto wheels have shown increased diameters of both femora andtibiafibulae, and suggest genetic effects on trainability (genotype-by-environmentinteractions). Reanalysis of previously published data on bonemasses of hind limbs revealed novel patterns of change in bonemass associated with access to wheels for 2 months. Withoutaccess to wheels, HR mice have significantly heavier tibiafibulaeand foot bones, whereas with chronic access to wheels, a significantincrease in foot bone mass that was linearly related to increasesin daily wheel running was observed. Mice exhibiting a recentlydiscovered small-muscle phenotype ("mini-muscle," [MM] causedby a Mendelian recessive gene), in which the mass of the tricepssurae muscle complex is 50% lower than in normal individuals,have significantly longer and thinner bones in the hind limb.We present new data for the ontogenetic development of musclemass in Control, HR, and MM phenotypes in mice of 1–7weeks postnatal age. Statistical comparisons reveal highly significantdifferences both in triceps surae mass and mass-corrected tricepssurae mass between normal and MM mice at all but the postnatalage of 1 week. Based on previously observed differences in distributionsof myosin isoforms in adult MM mice, we hypothesize that a reductionof myosin heavy-chain type-IIb isoforms with accounts for ourobserved ontogenetic changes in muscle mass.     

Bacillus stearothermophilus PcrA monomer is a single-stranded DNA translocase but not a processive helicase in vitro

Structural studies of the Bacillus stearothermophilus PcrA protein along with biochemical studies of the single-stranded (ss) DNA translocation activity of PcrA monomers have led to the suggestion that a PcrA monomer possesses processive helicase activity in vitro. Yet definitive studies testing whether the PcrA monomer possesses processive helicase activity have not been performed. Here we show, using single turnover kinetic methods, that monomers of PcrA are able to translocate along ssDNA, in the 3' to 5' direction, rapidly and processively, whereas these same monomers display no detectable helicase activity under the same solution conditions in vitro. The PcrA monomer ssDNA translocation activity, although necessary, is not sufficient for processive helicase activity, and thus the translocase and helicase activities of PcrA are separable. These results also suggest that the helicase activity of PcrA needs to be activated either by self-assembly or through interactions with accessory proteins. This same behavior is displayed by both the Escherichia coli Rep and UvrD monomers. Hence, all three of these SF1 enzymes are ssDNA translocases as monomers but do not display processive helicase activity in vitro unless activated. The fact that the translocase and helicase activities are separable suggests that each activity may be used for different functions in vivo.     

Identification of Escherichia coli DNA helicase IV with the use of a DNA helicase activity gel.

A DNA helicase activity gel was developed based on the assumption that DNA helicases could unwind double-stranded DNA in a polyacrylamide matrix. The production of single-stranded DNA was detected by staining the activity gel with acridine orange and visualizing the gel under long-wave UV light. The products of DNA helicase activities appeared as red bands within a green fluorescent background. A novel DNA helicase, called helicase IV, was detected in crude extracts of Escherichia coli with the use of the helicases activity gel assay. The new DNA helicase was purified to near homogeneity. The chromatographic properties and the sequence of its 11 amino-terminal residues proved that helicase IV was distinct from all of the previously described DNA helicases from E. coli.     

Role of ATP hydrolysis in the DNA translocase activity of the bovine papillomavirus (BPV-1) E1 helicase

The E1 protein of bovine papillomavirus type-1 is the viral replication initiator protein and replicative helicase. Here we show that the C-terminal ~300 amino acids of E1, that share homology with members of helicase superfamily 3 (SF3), can act as an autonomous helicase. E1 is monomeric in the absence of ATP but assembles into hexamers in the presence of ATP, single-stranded DNA (ssDNA) or both. A 16 base sequence is the minimum for efficient hexamerization, although the complex protects ~30 bases from nuclease digestion, supporting the notion that the DNA is bound within the protein complex. In the absence of ATP, or in the presence of ADP or the non–hydrolysable ATP analogue AMP–PNP, the interaction with short ssDNA oligonucleotides is exceptionally tight (T_1/2 > 6 h). However, in the presence of ATP, the interaction with DNA is destabilized (T_1/2 ~60 s). These results suggest that during the ATP hydrolysis cycle an internal DNA-binding site oscillates from a high to a low-affinity state, while protein–protein interactions switch from low to high affinity. This reciprocal change in protein–protein and protein–DNA affinities could be part of a mechanism for tethering the protein to its substrate while unidirectional movement along DNA proceeds.     

Triaminotriazine DNA helicase inhibitors with antibacterial activity

Screening of a chemical library in a DNA helicase assay involving the Pseudomonas aeruginosa DnaB helicase provided a triaminotriazine inhibitor with good antibacterial activity but associated cytotoxicity toward mammalian cells. Synthesis of analogs provided a few inhibitors that retained antibacterial activity and demonstrated a significant reduction in cytotoxicity. The impact of serum and initial investigations toward a mode of action highlight several features of this class of compounds as antibacterials.     

Rotations of the 2B sub-domain of E. coli UvrD helicase/translocase coupled to nucleotide and DNA binding

Escherichia coli UvrD is a superfamily 1 DNA helicase and single-stranded DNA (ssDNA) translocase that functions in DNA repair and plasmid replication and as an anti-recombinase by removing RecA protein from ssDNA. UvrD couples ATP binding and hydrolysis to unwind double-stranded DNA and translocate along ssDNA with 3′-to-5′ directionality. Although a UvrD monomer is able to translocate along ssDNA rapidly and processively, DNA helicase activity in vitro requires a minimum of a UvrD dimer. Previous crystal structures of UvrD bound to a ssDNA/duplex DNA junction show that its 2B sub-domain exists in a “closed” state and interacts with the duplex DNA. Here, we report a crystal structure of an apo form of UvrD in which the 2B sub-domain is in an “open” state that differs by an ∼ 160° rotation of the 2B sub-domain. To study the rotational conformational states of the 2B sub-domain in various ligation states, we constructed a series of double-cysteine UvrD mutants and labeled them with fluorophores such that rotation of the 2B sub-domain results in changes in fluorescence resonance energy transfer. These studies show that the open and closed forms can interconvert in solution, with low salt favoring the closed conformation and high salt favoring the open conformation in the absence of DNA. Binding of UvrD to DNA and ATP binding and hydrolysis also affect the rotational conformational state of the 2B sub-domain, suggesting that 2B sub-domain rotation is coupled to the function of this nucleic acid motor enzyme.     

Honey, I shrunk the DNA: DNA length as a probe for nucleic-acid enzyme activity

The replication, recombination, and repair of DNA are processes essential for the maintenance of genomic information and require the activity of numerous enzymes that catalyze the polymerization or digestion of DNA. This review will discuss how differences in elastic properties between single- and double-stranded DNA can be used as a probe to study the dynamics of these enzymes at the single-molecule level.     

AFM as a high-resolution imaging tool and a molecular bond force probe

This focused review summarizes certain aspects of recent developments in the use of atomic force microscope in high-resolution imaging of membrane-bound biological macromolecules and in molecular force probing of the interaction between biological conjugates. We point out the pros and cons in these approaches and critically analyze details involved in experiments.     

Escherichia coli DNA helicase II is active as a monomer

Helicases are thought to function as oligomers (generally dimers or hexamers). Here we demonstrate that although Escherichia coli DNA helicase II (UvrD) is capable of dimerization as evidenced by a positive interaction in the yeast two-hybrid system, gel filtration chromatography, and equilibrium sedimentation ultracentrifugation (Kd = 3.4 microM), the protein is active in vivo and in vitro as a monomer. A mutant lacking the C-terminal 40 amino acids (UvrDDelta40C) failed to dimerize and yet was as active as the wild-type protein in ATP hydrolysis and helicase assays. In addition, the uvrDDelta40C allele fully complemented the loss of helicase II in both methyl-directed mismatch repair and excision repair of pyrimidine dimers. Biochemical inhibition experiments using wild-type UvrD and inactive UvrD point mutants provided further evidence for a functional monomer. This investigation provides the first direct demonstration of an active monomeric helicase, and a model for DNA unwinding by a monomer is presented.     

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.     

Biochemical characterization of the DNA helicase activity of the escherichia coli RecQ helicase

We demonstrate that RecQ helicase from Escherichia coli is a catalytic helicase whose activity depends on the concentration of ATP, free magnesium ion, and single-stranded DNA-binding (SSB) protein. Helicase activity is cooperative in ATP concentration, with an apparent S(0.5) value for ATP of 200 microm and a Hill coefficient of 3.3 +/- 0.3. Therefore, RecQ helicase utilizes multiple, interacting ATP-binding sites to mediate double-stranded DNA (dsDNA) unwinding, implicating a multimer of at least three subunits as the active unwinding species. Unwinding activity is independent of dsDNA ends, indicating that RecQ helicase can unwind from both internal regions and ends of dsDNA. The K(M) for dsDNA is 0.5-0.9 microm base pairs; the k(cat) for DNA unwinding is 2.3-2.7 base pairs/s/monomer of RecQ helicase; and unexpectedly, helicase activity is optimal at a free magnesium ion concentration of 0.05 mm. Omitting Escherichia coli SSB protein lowers the rate and extent of dsDNA unwinding, suggesting that RecQ helicase associates with the single-stranded DNA (ssDNA) product. In agreement, the ssDNA-dependent ATPase activity is reduced in proportion to the SSB protein concentration; in its absence, ATPase activity saturates at six nucleotides/RecQ helicase monomer and yields a k(cat) of 24 s(-1). Thus, we conclude that SSB protein stimulates RecQ helicase-mediated unwinding by both trapping the separated ssDNA strands after unwinding and preventing the formation of non-productive enzyme-ssDNA complexes.     

Concomitant reconstitution of TraI-catalyzed DNA transesterase and DNA helicase activity in vitro

TraI protein of plasmid R1 possesses two activities, a DNA transesterase and a highly processive 5'-3' DNA helicase, which are essential for bacterial conjugation. Regulation of the functional domains of the enzyme is poorly understood. TraI cleaves supercoiled oriT DNA with site and strand specificity in vitro but fails to initiate unwinding from this site (nic). The helicase requires an extended region of adjacent single-stranded DNA to enter the duplex, yet interaction of purified TraI with oriT DNA alone or as an integral part of the IncF relaxosome does not melt sufficient duplex to load the helicase. This study aims to gain insights into the controlled initiation of both TraI-catalyzed activities. Linear double-stranded DNA substrates with a central region of sequence heterogeneity were used to trap defined lengths of R1 oriT sequence in unwound conformation. Concomitant reconstitution of TraI DNA transesterase and helicase activities was observed. Efficient helicase activity was measured on substrates containing 60 bases of open duplex but not on substrates containing < or =30 bases in open conformation. The additional presence of auxiliary DNA-binding proteins TraY and Escherichia coli integration host factor did not stimulate TraI activities on these substrates. This model system offers a novel approach to investigate factors controlling helicase loading and the directionality of DNA unwinding from nic.     

The scanning probe microscope as a novel genomic analysis tool

We have developed a novel and efficient genomic analysis tool that combines scanning probe microscopy (SPM) and image processing with molecular biology techniques to accelerate genomic research. To examine the correlation between chromosome volume and DNA content, we scanned human metaphase chromosome sets with an atomic force microscope to examine the chromosome volume distribution. We found that the chromosome volume distribution agreed with DNA length distribution (obtained from a public database), and that the short arm to long arm volume ratio showed good agreement with the genomic position of the centromere. We were also able to predict the genomic position of an arbitrary gene marker with high accuracy by combining a scanning near-field optical/atomic force microscope and image processing techniques using fluorescence in situ hybridization. Thus, a novel SPM-based system developed here will be an effective tool to rapidly and accurately map DNA markers and construct physical map, which contributes to the advancement of genomic science.     

Semi-intact CHO and endothelial cells: a tool to probe the control of integrin activity?

An in vitro assay has been developed using semi-intact cells, made with the bacterial toxin streptolysin O, in order to measure integrin activity in relation to the cytosol environment. In this assay, the cytosolic content can easily be modified while the receptor binding activity is measured by monitoring the interaction of specific radiolabeled substrates with the cell surface. Using two different cell types, i.e., wild-type Chinese hamster ovary cells and human endothelial cells in culture, it has been shown that the binding activities of the fibronectin and fibrinogen receptors become cytosol-dependent on perforated cells. Furthermore, this control depends on micromolar concentrations of intracellular calcium, suggesting that calcium or calcium binding protein(s) may play a key role in controlling integrin activity.     

RecG helicase activity at three- and four-strand DNA structures.

The RecG helicase of Escherichia coli is necessary for efficient recombination and repair of DNA in vivo and has been shown to catalyse the unwinding of DNA junctions in vitro. Despite these findings, the precise role of RecG remains elusive. However, models have been proposed in which RecG promotes the resolution of linked duplexes by targeting three-strand junctions present at D-loops. One such model postulates that RecG catalyses the formation of four-strand (Holliday) junctions from three-strand junctions. To test this model, the DNA binding and unwinding activities of RecG were analysed using synthetic three- and four-strand junctions. The substrate specificity of RecG was found to depend critically on the concentrations of ATP and MgCl(2)and under certain conditions RecG preferentially unwound three-strand junction DNA. This was at least partly due to the larger inhibitory effect of MgCl(2)on the binding of four-strand as opposed to three-strand junctions by RecG. Thus RecG may be targeted to three-strand junctions in vivo whilst still being able to branch migrate the four-strand junctions formed as a result of the initial helicase reaction. The increase in the dissociation constant of RecG on conversion of a three-strand into a four-strand junction may also facilitate resolution of the four-strand junction by the RuvABC complex.     

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.