Sequence-specific fluorescent labeling of double-stranded DNA observed at the single molecule level

Fluorescent labeling of a short sequence of double-stranded DNA (dsDNA) was achieved by ligating a labeled dsDNA fragment to a stem–loop triplex forming oligonucleotide (TFO). After the TFO has wound around the target sequence by ligand-induced triple helix formation, its extremities hybridize to each other, leaving a dangling single-stranded sequence, which is then ligated to a fluorescent dsDNA fragment using T4 DNA ligase. A non-repeated 15 bp sequence present on lambda DNA was labeled and visualized by fluorescence microscopy after DNA combing. The label was found to be attached at a specific position located at 4.2 ± 0.5 kb from one end of the molecule, in agreement with the location of the target sequence for triple helix formation (4.4 kb from one end). In addition, an alternative combing process was noticed in which a DNA molecule becomes attached to the combing slide from the label rather than from one of its ends. The method described herein provides a new tool for the detection of very short sequences of dsDNA and offers various perspectives in the micromanipulation of single DNA molecules.     

Manipulation of single polymerase-DNA complexes: A mechanical view of DNA unwinding during replication

Comment on: Morin JA, et al. Proc Natl Acad Sci USA 2012; 109:8115-20.DNA replication requires overcoming the energetic barrier associated with the base pair melting of its double helix and a fine-tuned coordination between the processes of DNA unwinding and DNA replication. One intriguing question that remains poorly understood is the exact mechanism of the coupling of these two reactions. In some organisms, these activities are coupled within the same protein, like in the case of the phage Phi29 DNA polymerase. This polymerase works as a hybrid polymerase-helicase, because it presents an amino acid insertion that together with other protein domains forms a narrow tunnel around the template strand. This topological restriction is similar to the one imposed by hexameric helicases at the fork junction and promotes the separation of the fork ahead.¹ The Phi29 DNA polymerase, therefore, constitutes a simple, good model system to understand the basic mechanistic principles of the coupling between DNA replication and unwinding activities: the polymerase may behave as a “passive” unwinding motor, if translocation of the protein traps transient unwinding fluctuations of the fork, or as an “active” motor, if the polymerase actively destabilizes the duplex DNA at the junction. Therefore, factors that affect the stability of the fork junction, as DNA sequence or mechanical destabilization of the fork, will have a stronger effect on the unwinding kinetics of a “passive” motor than on an “active” one.To determine the DNA unwinding mechanism of the Phi29 DNA polymerase, we used optical tweezers to measure at single molecule level the effect of DNA sequence and destabilizing forces on the fork on the rates of strand displacement (replication and unwinding are tightly coupled, Δx₁, Fig. 1A) and primer extension (replication of the displaced complementary strand without unwinding, Δx₂, Fig. 1A) of two polymerases: the wild-type Phi29 DNA polymerase and a strand displacement deficient variant, which bears a couple of mutations that may affect the stability of the tunnel required for unwinding.² We quantified the free energy of interaction between the polymerase and the DNA fork, ΔG_int, and the range of this interaction, M, through a theoretical analysis of the dependence of the replication, unwinding and pause kinetics on the DNA sequence and force.^3,4Open in a separate windowFigure 1. (A) Schematic representation of the experimental design (not to scale). A single DNA hairpin was attached to functionalized beads inside a fluidics chamber. One strand of the hairpin is attached through a dsDNA handle to a bead held in the optical trap (top), while the complementary strand is attached to a bead on top of a mobile micropipette (bottom). At a constant force, after flowing the nucleotides into the reaction chamber, the strand displacement and primer extension rates of the polymerase are detected as a change in distance between the beads, Δx₁ and Δx₂, respectively. (B) Representative replication activity of a single mutant polymerase molecule. Long pauses are observed only during the strand displacement reaction. (C) Mechanistic distinction between passive and active unwinding. The cartoon illustrates the degree of activeness in DNA unwinding of different replicative helicases⁶ and the Phi29 DNA polymerase.Our results show that while the primer extension rates of both polymerases are force- and sequence-independent their average unwinding rates are sensitive to these two variables, although with different intensity. As expected, the dsDNA fork presents a much stronger physical barrier to the mutant polymerase unwinding. Qualitative reasoning might suggest that the observed differences imply different “activeness” of the unwinding mechanism of each polymerase. However, the inclusion of the pause kinetics of each polymerase in our model revealed that they use the same active mechanism; they both destabilize the two nearest base pairs of the fork (M = 2) with an interaction energy ΔG_int = 2 k_BT per base pair. These results suggest that mutations affecting the stability of the tunnel required for unwinding do not decrease the “activeness” of the motor but instead increase the probability of the unwinding mechanism to fail upon encountering a closed fork junction, inducing the entrance of the mutant polymerase into a long-lived inactive pause state (Fig. 1B). These results bring out the importance to consider pause kinetics to accurately quantify the actual unwinding mechanism of the Phi29 DNA polymerase or any other nucleic acid unwinding motor in which pauses are relevant during its operation. The presence of pauses obscures the actual pause-free rates of the motor and can lead to misleading results when they are not properly accounted.Our data are consistent with a model in which the closed template tunnel that wraps around the template strand allows the Phi29 DNA polymerase to maintain a sharp bending of this strand (essential for template reading in all replicative polymerases) and a bending of the complementary strand, due to its steric exclusion, at a closed fork junction. Bending of the two strands would generate mechanical stress at the junction promoting its active destabilization. A less stable tunnel, as in the mutant polymerase, will not be able to keep the mechanical stress at a closed fork junction, in this case the fork pressure would induce loosening of the correct protein-DNA interactions favoring the entrance to a polymerization inactive state.Similar mechanisms for mechanical destabilization of the fork junction can be envisioned for other DNA replication systems in which a DNA polymerase and a helicase work in coordination. In these systems, the leading strand can be sharply bent by the steric exclusion induced by the helicase and by the functional binding of the polymerase generating effective mechanical stress at the fork junction to account for efficient unwinding during replication. These implications are further supported by recent single molecule studies using magnetic tweezers that describe a collaborative coupling of this nature between the activities of the bacteriophage T4 DNA polymerase and DNA helicase.⁵     

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.     

Conformation dependent binding of netropsin and distamycin to DNA and DNA model polymers

The binding of the antibiotics netropsin and distamycin A to DNA has been studied by thermal melting, CD and sedimentation analysis. Netropsin binds strongly at antibiotic/nucleotide ratios up to at least 0.05. CD spectra obtained using DNA model polymers reveal that netropsin binds tightly to poly (dA) · poly (dT), poly (dA-dT) · poly(dA-dT) and poly (dI-dC) · poly (dI-dC) but poorly, if at all, to poly (dG) · poly (dC). Binding curves obtained with calf thymus DNA reveal one netropsin-binding site per 6.0 nucleotides (K_a=2.9 · 10⁵ M⁻¹); corresponding values for distamycin A are one site per 6.1 nucleotides with K_a= 11.6 · 10⁵ M⁻¹. Binding sites apparently involve predominantly A·T-rich sequences whose specific conformation determines their high affinity for the two antibiotics. It is suggested that the binding is stabilized primarily by hydrogen bonding and electrostatic interactions probably in the narrow groove of the DNA helix, but without intercalation. Any local structural deformation of the helix does not involve unwinding greater than approximately 3° per bound antibiotic molecule.     

Programmable cleavage of linear double-stranded DNA by combined action of Argonaute CbAgo from Clostridium butyricum and nuclease deficient RecBC helicase from E. coli

Prokaryotic Argonautes (pAgos) use small nucleic acids as specificity guides to cleave single-stranded DNA at complementary sequences. DNA targeting function of pAgos creates attractive opportunities for DNA manipulations that require programmable DNA cleavage. Currently, the use of mesophilic pAgos as programmable endonucleases is hampered by their limited action on double-stranded DNA (dsDNA). We demonstrate here that efficient cleavage of linear dsDNA by mesophilic Argonaute CbAgo from Clostridium butyricum can be activated in vitro via the DNA strand unwinding activity of nuclease deficient mutant of RecBC DNA helicase from Escherichia coli (referred to as RecB^exo–C). Properties of CbAgo and characteristics of simultaneous cleavage of DNA strands in concurrence with DNA strand unwinding by RecB^exo–C were thoroughly explored using 0.03–25 kb dsDNAs. When combined with RecB^exo–C, CbAgo could cleave targets located 11–12.5 kb from the ends of linear dsDNA at 37°C. Our study demonstrates that CbAgo with RecB^exo–C can be programmed to generate DNA fragments with custom-designed single-stranded overhangs suitable for ligation with compatible DNA fragments. The combination of CbAgo and RecB^exo–C represents the most efficient mesophilic DNA-guided DNA-cleaving programmable endonuclease for in vitro use in diagnostic and synthetic biology methods that require sequence-specific nicking/cleavage of linear dsDNA at any desired location.     

Double Strand Break Unwinding and Resection by the Mycobacterial Helicase-Nuclease AdnAB in the Presence of Single Strand DNA-binding Protein (SSB)

Mycobacterial AdnAB is a heterodimeric DNA helicase-nuclease and 3′ to 5′ DNA translocase implicated in the repair of double strand breaks (DSBs). The AdnA and AdnB subunits are each composed of an N-terminal motor domain and a C-terminal nuclease domain. Inclusion of mycobacterial single strand DNA-binding protein (SSB) in reactions containing linear plasmid dsDNA allowed us to study the AdnAB helicase under conditions in which the unwound single strands are coated by SSB and thereby prevented from reannealing or promoting ongoing ATP hydrolysis. We found that the AdnAB motor catalyzed processive unwinding of 2.7–11.2-kbp linear duplex DNAs at a rate of ∼250 bp s⁻¹, while hydrolyzing ∼5 ATPs per bp unwound. Crippling the AdnA phosphohydrolase active site did not affect the rate of unwinding but lowered energy consumption slightly, to ∼4.2 ATPs bp⁻¹. Mutation of the AdnB phosphohydrolase abolished duplex unwinding, consistent with a model in which the “leading” AdnB motor propagates a Y-fork by translocation along the 3′ DNA strand, ahead of the “lagging” AdnA motor domain. By tracking the resection of the 5′ and 3′ strands at the DSB ends, we illuminated a division of labor among the AdnA and AdnB nuclease modules during dsDNA unwinding, whereby the AdnA nuclease processes the unwound 5′ strand to liberate a short oligonucleotide product, and the AdnB nuclease incises the 3′ strand on which the motor translocates. These results extend our understanding of presynaptic DSB processing by AdnAB and engender instructive comparisons with the RecBCD and AddAB clades of bacterial helicase-nuclease machines.     

Displacement of a DNA binding protein by Dda helicase

Bacteriophage T4 Dda helicase has recently been shown to be active as a monomer for unwinding of short duplex oligonucleotides and for displacing streptavidin from 3′-biotinylated oligonucleotides. However, its activity for streptavidin displacement and DNA unwinding has been shown to increase as the number of Dda molecules bound to the substrate molecule increases. A substrate was designed to address the ability of Dda to displace DNA binding proteins. A DNA binding site for the Escherichia coli trp repressor was introduced into an oligonucleotide substrate for Dda helicase containing single-stranded overhang. Here we show that a Dda monomer is insufficient to displace the E.coli trp repressor from dsDNA under single turnover conditions, although the substrate is unwound and the repressor displaced when the single-stranded overhang is long enough to accommodate two Dda molecules. The quantity of product formed increases when the substrate is able to accommodate more than two Dda molecules. These results indicate that multiple Dda molecules act to displace DNA binding proteins in a manner that correlates with the DNA unwinding activity and streptavidin displacement activity. We suggest a cooperative inchworm model to describe the activities of Dda helicase.     

Folding of the cocaine aptamer studied by EPR and fluorescence spectroscopies using the bifunctional spectroscopic probe Ç

The cocaine aptamer is a DNA molecule that binds cocaine at the junction of three helices. The bifunctional spectroscopic probe Ç was incorporated independently into three different positions of the aptamer and changes in structure and dynamics upon addition of the cocaine ligand were studied. Nucleoside Ç contains a rigid nitroxide spin label and can be studied directly by electron paramagnetic resonance (EPR) spectroscopy and fluorescence spectroscopy after reduction of the nitroxide to yield the fluoroside Ç^f. Both the EPR and the fluorescence data for aptamer 2 indicate that helix III is formed before cocaine binding. Upon addition of cocaine, increased fluorescence of a fully base-paired Ç^f, placed at the three-way junction in helix III, was observed and is consistent with a helical tilt from a coaxial stack of helices II and III. EPR and fluorescence data clearly show that helix I is formed upon addition of cocaine, concomitant with the formation of the Y-shaped three-way helical junction. The EPR data indicate that nucleotides in helix I are more mobile than nucleotides in regular duplex regions and may reflect increased dynamics due to the short length of helix I.     

Kinetics of DNA Unwinding by the RecD2 Helicase from Deinococcus radiodurans

RecD2 from Deinococcus radiodurans is a superfamily 1 DNA helicase that is homologous to the Escherichia coli RecD protein but functions outside the context of RecBCD enzyme. We report here on the kinetics of DNA unwinding by RecD2 under single and multiple turnover conditions. There is little unwinding of 20-bp substrates by preformed RecD2-dsDNA complexes when excess ssDNA is present to trap enzyme molecules not bound to the substrate. A shorter 12-bp substrate is unwound rapidly under single turnover conditions. The 12-bp unwinding reaction could be simulated with a mechanism in which the DNA is unwound in two kinetic steps with rate constant of k_unw = 5.5 s⁻¹ and a dissociation step from partially unwound DNA of k_off = 1.9 s⁻¹. These results indicate a kinetic step size of about 3–4 bp, unwinding rate of about 15–20 bp/s, and low processivity (p = 0.74). The reaction time courses with 20-bp substrates, determined under multiple turnover conditions, could be simulated with a four-step mechanism and rate constant values very similar to those for the 12-bp substrate. The results indicate that the faster unwinding of a DNA substrate with a forked end versus only a 5′-terminal single-stranded extension can be accounted for by a difference in the rate of enzyme binding to the DNA substrates. Analysis of reactions done with different RecD2 concentrations indicates that the enzyme forms an inactive dimer or other oligomer at high enzyme concentrations. RecD2 oligomers can be detected by glutaraldehyde cross-linking but not by size exclusion chromatography.     

Force spectroscopy and fluorescence microscopy of dsDNA–YOYO-1 complexes: implications for the structure of dsDNA in the overstretching region

When individual dsDNA molecules are stretched beyond their B-form contour length, they reveal a structural transition in which the molecule extends 1.7 times its contour length. The nature of this transition is still a subject of debate. In the first model, the DNA helix unwinds and combined with the tilting of the base pairs (which remain intact), results in a stretched form of DNA (also known as S-DNA). In the second model the base pairs break resulting effectively in two single-strands, which is referred to as force-induced melting. Here a combination of optical tweezers force spectroscopy with fluorescence microscopy was used to study the structure of dsDNA in the overstretching regime. When dsDNA was stretched in the presence of 10 nM YOYO-1 an initial increase in total fluorescence intensity of the dye–DNA complex was observed and at an extension where the dsDNA started to overstretch the fluorescence intensity leveled off and ultimately decreased when stretched further into the overstretching region. Simultaneous force spectroscopy and fluorescence polarization microscopy revealed that the orientation of dye molecules did not change significantly in the overstretching region (78.0°± 3.2°). These results presented here clearly suggest that, the structure of overstretched dsDNA can be explained accurately by force induced melting.     

Inhibition of unwinding and ATPase activities of pea MCM6 DNA helicase by actinomycin and nogalamycin

Pea mini-chromosome maintenance 6 (MCM6) single subunit (93 kDa) forms homohexamer (560 kDa) and contains an ATP-dependent and replication fork stimulated 3′ to 5′ DNA unwinding activity along with intrinsic DNA-dependent ATPase and ATP-binding activities¹ (Plant Mol Biol 2010; DOI: 10.1007/s11103-010-9675-7). Here, we have determined the effect of various DNA-binding agents, such as actinomycin, nogalamycin, daunorubicin, doxorubicin, distamycin, camptothecin, cyclophosphamide, ellipticine, VP-16, novobiocin, netropsin, cisplatin, mitoxantrone and genistein on the DNA unwinding and ATPase activities of the pea MCM6 DNA helicase. The results show that actinomycin and nogalamycin inhibited the DNA helicase (apparent Ki values of 10 and 1 µM, respectively) and ATPase (apparent Ki values of 100 and 17 µM, respectively) activities. Although, daunorubicin and doxorubicin also inhibited the DNA helicase activity of pea MCM6, but with less efficiency; however, these could not inhibit the ATPase activity. These results suggest that the intercalation of the inhibitors into duplex DNA generates a complex that impedes translocation of MCM6, resulting in the inhibitions of the activities. This study could be useful in our better understanding of the mechanism of plant nuclear DNA helicase unwinding.Key words: ATPase, actinomycin, DNA-binding agents, DNA helicase, nogalamycin, pea MCM6     

Temperature Dependences of Torque Generation and Membrane Voltage in the Bacterial Flagellar Motor

In their natural habitats bacteria are frequently exposed to sudden changes in temperature that have been shown to affect their swimming. With our believed to be new methods of rapid temperature control for single-molecule microscopy, we measured here the thermal response of the Na⁺-driven chimeric motor expressed in Escherichia coli cells. Motor torque at low load (0.35 μm bead) increased linearly with temperature, twofold between 15°C and 40°C, and torque at high load (1.0 μm bead) was independent of temperature, as reported for the H⁺-driven motor. Single cell membrane voltages were measured by fluorescence imaging and these were almost constant (∼120 mV) over the same temperature range. When the motor was heated above 40°C for 1–2 min the torque at high load dropped reversibly, recovering upon cooling below 40°C. This response was repeatable over as many as 10 heating cycles. Both increases and decreases in torque showed stepwise torque changes with unitary size ∼150 pN nm, close to the torque of a single stator at room temperature (∼180 pN nm), indicating that dynamic stator dissociation occurs at high temperature, with rebinding upon cooling. Our results suggest that the temperature-dependent assembly of stators is a general feature of flagellar motors.     

Characterization of the helicase activity of the Escherichia coli RecBCD enzyme using a novel helicase assay

We describe an assay to measure the extent of enzymatic unwinding of DNA by a DNA helicase. This assay takes advantage of the quenching of the intrinsic protein fluorescence of Escherichia coli SSB protein upon binding to ssDNA and is used to characterize the DNA unwinding activity of recBCD enzyme. Unwinding in this assay is dependent on the presence of recBCD enzyme and linear dsDNA, is consistent with the known properties of recBCD enzyme, and closely parallels other methods for measuring recBCD enzyme helicase activity. The effects of varying temperature, substrate concentrations, enzyme concentration, and mono- and divalent salt concentrations on the helicase activity of recBCD enzyme were characterized. The apparent Km values for recBCD enzyme helicase activity on linear M13 dsDNA molecules at 25 degrees C are 0.6 nM dsDNA molecules and 130 microM ATP, respectively. The apparent turnover number for unwinding is approximately 15 microM base pairs s-1 (microM recBCD enzyme)-1. When this rate is corrected for the observed stoichiometry of recBCD enzyme binding to dsDNA, kcat for helicase activity corresponds to an unwinding rate of approximately 250 base pairs of DNA s-1 (functional recBCD complex)-1 at 25 degrees C. At 37 degrees C, the apparent Km value for dsDNA molecules was the same as that at 25 degrees C, but the apparent turnover number became 56 microM base pairs s-1 (microM recBCD enzyme)-1 [or 930 base pairs s-1 (functional recBCD complex)-1 when corrected for observed stoichiometry]. With increasing NaCl concentration, kcat peaks at 100 mM, and the apparent Km value for dsDNA increases by 3-fold at 200 mM NaCl. In the presence of 5 mM calcium acetate, the apparent Km value is increased by 3-fold, and kcat decreased by 20-30%. We have also shown that recBCD enzyme molecules are able to catalytically unwind additional dsDNA substrates subsequent to initiation, unwinding, and dissociation from a previous dsDNA molecule.     

Dissecting the Dynamic Pathways of Stereoselective DNA Threading Intercalation

DNA intercalators that have high affinity and slow kinetics are developed for potential DNA-targeted therapeutics. Although many natural intercalators contain multiple chiral subunits, only intercalators with a single chiral unit have been quantitatively probed. Dumbbell-shaped DNA threading intercalators represent the next order of structural complexity relative to simple intercalators, and can provide significant insights into the stereoselectivity of DNA-ligand intercalation. We investigated DNA threading intercalation by binuclear ruthenium complex [μ-dppzip(phen)₄Ru₂]⁴⁺ (Piz). Four Piz stereoisomers are defined by the chirality of the intercalating subunit (Ru(phen)₂dppz) and the distal subunit (Ru(phen)₂ip), respectively, each of which can be either right-handed (Δ) or left-handed (Λ). We used optical tweezers to measure single DNA molecule elongation due to threading intercalation, revealing force-dependent DNA intercalation rates and equilibrium dissociation constants. The force spectroscopy analysis provided the zero-force DNA binding affinity, the equilibrium DNA-ligand elongation Δx_eq, and the dynamic DNA structural deformations during ligand association x_on and dissociation x_off. We found that Piz stereoisomers exhibit over 20-fold differences in DNA binding affinity, from a K_d of 27 ± 3 nM for (Δ,Λ)-Piz to a K_d of 622 ± 55 nM for (Λ,Δ)-Piz. The striking affinity decrease is correlated with increasing Δx_eq from 0.30 ± 0.02 to 0.48 ± 0.02 nm and x_on from 0.25 ± 0.01 to 0.46 ± 0.02 nm, but limited x_off changes. Notably, the affinity and threading kinetics is 10-fold enhanced for right-handed intercalating subunits, and 2- to 5-fold enhanced for left-handed distal subunits. These findings demonstrate sterically dispersed transition pathways and robust DNA structural recognition of chiral intercalators, which are critical for optimizing DNA binding affinity and kinetics.     

A rapid and sensitive method for the screening of DNA intercalating antibiotics

An improved, rapid and inexpensive gel mobility shift assay was developed for the screening of anthracycline antibiotics. The assay based on the intercalation activity of these molecules into dsDNA was used to assess the activity of partially purified antibiotics. Detection limits were of 0.1 ng ml^–1 with an average run time of 2 h. The assay is potentially useful for high throughput screening in bioprospecting, for monitoring fermentation production phases and downstream purification process.     

Specific inhibition of the E.coli RecBCD enzyme by Chi sequences in single-stranded oligodeoxyribonucleotides

RecBCD is an ATP-dependent helicase and exonuclease which generates 3′ single-stranded DNA (ssDNA) ends used by RecA for homologous recombination. The exonuclease activity is altered when RecBCD encounters a Chi sequence (5′-GCTGGTGG-3′) in double-stranded DNA (ds DNA), an event critical to the generation of the 3′-ssDNA. This study tests the effect of ssDNA oligonucleotides having a Chi sequence (Chi⁺) or a single base change that abolishes the Chi sequence (Chi^o), on the enzymatic activities of RecBCD. Our results show that a 14 and a 20mer with Chi⁺ in the center of the molecule inhibit the exonuclease and helicase activities of RecBCD to a greater extent than the corresponding Chi^o oligonucleotides. Oligonucleotides with the Chi sequence at one end, or the Chi sequence alone in an 8mer, failed to show Chi-specific inhibition of RecBCD. Thus, Chi recognition requires that Chi be flanked by DNA at either end. Further experiments indicated that the oligonucleotides inhibit RecBCD from binding to its dsDNA substrate. These results suggest that a specific site for Chi recognition exists on RecBCD, which binds Chi with greater affinity than a non-Chi sequence and is probably adjacent to non-specific DNA binding sites.     

Low-fidelity DNA synthesis by human DNA polymerase theta

Human DNA polymerase theta (pol θ or POLQ) is a proofreading-deficient family A enzyme implicated in translesion synthesis (TLS) and perhaps in somatic hypermutation (SHM) of immunoglobulin genes. These proposed functions and kinetic studies imply that pol θ may synthesize DNA with low fidelity. Here, we show that when copying undamaged DNA, pol θ generates single base errors at rates 10- to more than 100-fold higher than for other family A members. Pol θ adds single nucleotides to homopolymeric runs at particularly high rates, exceeding 1% in certain sequence contexts, and generates single base substitutions at an average rate of 2.4 × 10⁻³, comparable to inaccurate family Y human pol κ (5.8 × 10⁻³) also implicated in TLS. Like pol κ, pol θ is processive, implying that it may be tightly regulated to avoid deleterious mutagenesis. Pol θ also generates certain base substitutions at high rates within sequence contexts similar to those inferred to be copied by pol θ during SHM of immunoglobulin genes in mice. Thus, pol θ is an exception among family A polymerases, and its low fidelity is consistent with its proposed roles in TLS and SHM.     

Sedimentation Coefficient and Fragility under Hydrodynamic Shear as Measures of Molecular Weight of the DNA of Phage T5

T5 DNA molecules resemble fragments of T2 DNA of molecular weight 84 × 10⁶ with respect to sedimentation coefficient and susceptibility to breakage under hydrodynamic shear. The sedimentation coefficient falls by the same factor when either T2 or T5 DNA is broken at its characteristic critical shear rate. At a given high rate of shear, both DNA's are broken into fragments exhibiting the same sedimentation coefficient. It follows that 84 × 10⁶ is a proper estimate of the molecular weight of T5 DNA, and that particles of phage T5, like those of T2, contain a single DNA molecule.     

Kinetic Characterization of Nonmuscle Myosin IIB at the Single Molecule Level

Nonmuscle myosin IIB (NMIIB) is a cytoplasmic myosin, which plays an important role in cell motility by maintaining cortical tension. It forms bipolar thick filaments with ∼14 myosin molecule dimers on each side of the bare zone. Our previous studies showed that the NMIIB is a moderately high duty ratio (∼20–25%) motor. The ADP release step (∼0.35 s⁻¹) of NMIIB is only ∼3 times faster than the rate-limiting phosphate release (0.13 ± 0.01 s⁻¹). The aim of this study was to relate the known in vitro kinetic parameters to the results of single molecule experiments and to compare the kinetic and mechanical properties of single- and double-headed myosin fragments and nonmuscle IIB thick filaments. Examination of the kinetics of NMIIB interaction with actin at the single molecule level was accomplished using total internal reflection fluorescence (TIRF) with fluorescence imaging with 1-nm accuracy (FIONA) and dual-beam optical trapping. At a physiological ATP concentration (1 mm), the rate of detachment of the single-headed and double-headed molecules was similar (∼0.4 s⁻¹). Using optical tweezers we found that the power stroke sizes of single- and double-headed heavy meromyosin (HMM) were each ∼6 nm. No signs of processive stepping at the single molecule level were observed in the case of NMIIB-HMM in optical tweezers or TIRF/in vitro motility experiments. In contrast, robust motility of individual fluorescently labeled thick filaments of full-length NMIIB was observed on actin filaments. Our results are in good agreement with the previous steady-state and transient kinetic studies and show that the individual nonprocessive nonmuscle myosin IIB molecules form a highly processive unit when polymerized into filaments.     

Structure of the DNA of the adenovirus 7-simian virus 40 hybrid, e46, by electron microscopy

The DNA molecule of the adenovirus 7-simian virus (SV) 40 hybrid, E46⁺, contains a single substitution of SV40 DNA located about 0.05 adenovirus 7 lengths from one end (arbitrarily designated the left end). The left to right direction in the SV40 DNA segment of the hybrid corresponds to the clockwise direction in the SV40 physical map. The left end point of the segment maps at about SV40 map position 0.50 ± 0.01 and the right end point at about SV40 map position 0.66 ± 0.01. The region between SV40 map positions 0.71 and 0.11 (clockwise) is deleted. Thus, the region between SV40 map position 0.50 and 0.66 (clockwise) is repeated in tandem.