In an embodiment according to the invention, a system includes a translation stage, a substrate having a first binding point suitable for attachment of a first end of a filament, a magnet opposite of the substrate, a magnetic probe having a magnetic moment, an azimuthal orientation, and a second binding point suitable for attachment of a second end of the filament, positioned between the substrate and the magnet, and an imaging device near to the substrate, magnet, and magnetic probe. A translation stage can be attached to the substrate. A translation stage can be attached to the magnet. The imaging device can determine the azimuthal orientation of the magnetic probe. The second binding point of the magnetic probe can be offset from the magnetic moment.
In an embodiment, the magnetic moment of the magnetic probe is approximately parallel to an orientation axis passing through the first binding point and the second binding point. The translation stage can have 2 axes of motion. The magnet can be a single permanent magnet. The single permanent magnet can be affixed to a z-stage translatable in a direction approximately parallel to the orientation axis. The magnet can be an electromagnet, and can have a variable magnetic field. The magnetic probe can include a magnetic bead and a lever. The magnetic moment of the magnetic probe can pass through the magnetic bead. The lever can include the second binding point. The magnetic probe can include a superparamagnetic material. The filament can include a macromolecule.
A method for determining the torque applied to a filament according to the invention includes affixing a first end of the filament to a substrate, affixing a second end of the filament to a magnetic probe having an azimuthal orientation, applying an external magnetic field having a magnetic axis to move the magnetic probe and elongate the filament along an orientation axis passing through the first end and the second end of the filament, translating the first end of the filament relative to the magnetic axis (for example, by translating the substrate and/or the magnetic field) to change the azimuthal orientation of the magnetic probe and impose twist on the filament, obtaining images of the magnetic probe at a plurality of successive times, using the images to determine the azimuthal orientation of the magnetic probe at the successive times, obtaining a probability distribution of azimuthal orientations from the azimuthal orientations at the successive times, and determining the torque on the filament from the probability distribution of azimuthal orientations. The filament can be a polynucleotide. The substrate can be translated in a curve having a winding number about the magnetic probe. The winding number can be fractional, for example, one-half (0.5) revolution or one and one half (1.5) revolutions. The torque on the filament as a function of the azimuthal orientation and/or the winding number can be determined. The external magnetic field can be varied to vary an elongation force along the orientation axis of the filament. The torque as a function of the elongation force and the azimuthal orientation and/or the winding number can be varied.
a-1c present a system for single molecule torque measurement.
a presents a bright-field image of a nanorod-bead magnetic probe (bar=1 μm).
a presents the horizontal angular trap stiffness in the conventional two-magnet configuration.
a shows a scanning electron micrograph of the aluminum oxide template used for nanorod electrodeposition.
a-11c presents the deviation of the nanorod from the horizontal (vertical (altitude) angle).
a-14b shows Ni—Pt nanorods coated with tetramethylrhodamine conjugated Neutravidin.
Embodiments of the invention are discussed in detail below. In describing embodiments, specific terminology is employed for the sake of clarity. However, the invention is not intended to be limited to the specific terminology so selected. A person skilled in the relevant art will recognize that other equivalent components can be employed and other methods developed without parting from the spirit and scope of the invention. All references cited herein are incorporated by reference as if each had been individually incorporated.
Torsional stress in linear biopolymers such as DNA and chromatin has important consequences for nanoscale biological processes. We have developed a new method to directly measure torque on single molecules. Using a cylindrical magnet, we manipulate a novel probe consisting of a nanorod with a 0.1 μm ferromagnetic segment coupled to a magnetic bead according to an embodiment of the current invention. We achieve controlled introduction of turns into the molecule, precise measurement of torque and molecule extension as a function of the number of turns at low pulling force. We show torque measurement of single DNA molecules and demonstrate for the first time measurements of single chromatin fibers.
DNA and other linear biopolymers accumulate torsional stress under the action of a rotary force or torque. This property has important biological implications, for example, torsional stress affects the action of enzymes that act on DNA.1-3 Fundamental biological processes such as DNA replication and transcription involve biological nanomachines that exert torque on double stranded (ds) DNA and chromatin.4, 5 Thus, in order to reveal the mechanisms and energetics of these processes, it is imperative to have tools to measure the torque required to twist linear biopolymers, such as DNA and chromatin. Understanding how biological processes and linear biopolymers are affected by torsional stress is important in the design of chemotherapeutic drugs,6 and applications involving DNA biological machines.7 Moreover, the ability to measure the torque of single molecules is important in understanding molecular structure, such as the chromatin structure;8 and, in general, an essential tool to study the torsional properties of nanoscale linear biopolymers.
The dependence of torque on twist for DNA has been measured with optical angular trapping methods,9-11 and has been analyzed from viscous drag forces.12 However, like other biopolymers, the structure of DNA is sensitive to pulling force, and these techniques employ pulling forces greater than 1 pN, sufficient for melting duplex DNA when negative twists are introduced. DNA and chromatin in vivo are usually free from stretching forces and hence it is of fundamental interest to study these filaments or fibers using a device that can measure torque at low pulling force. Twisting a single molecule at low pulling force can be achieved using magnetic tweezers. Magnetic tweezers techniques have been used to study naked DNA,13, 14 chromatin,8, 15-17 and enzymes that act on DNA.2, 18-22 The conventional magnetic tweezers setup, however, does not allow measuring single molecule torques (˜10 pN·nm [ref.9]) because, as we show below, they do not produce a measurable change in the angular orientation of the probe used to twist the molecule.
To allow measurement of torque at low pulling forces (0.1-1.5 pN), we have developed a new magnetic tweezers configuration (
In order to study the torsional properties of DNA and other linear biopolymers at low pulling force in a single molecule experiment, there are four main aspects. First, we can be able to introduce turns into the molecule. This can be accomplished by first linking one end of the molecule to the nanorod and the other end to the glass substrate, and then rotating the nanorod-bead probe. The probe can be rotated by exposing the probe to a rotating magnetic field. Second, we can be able to measure torque at any configuration (i.e., number of turns). This can be achieved in the following way. Under equilibrium conditions the magnetic field holds the probe at a given angular orientation but sufficiently weakly to allow thermal fluctuations. Torque can be calculated from the change in the angular distribution of the probe before and after introducing turns into the molecule. To do this, the probe can be confined in a weak trap, so that the orientational change can be observed. Third, we can measure the extension of the molecule perpendicular to the surface. This can be measured from analysis of the interference pattern from the bead attached to the nanorod24. Fourth, we can apply and measure a small vertical force. This force can be applied to the molecule through the probe and can be the result of a vertical gradient in the magnetic field. This force can keep the molecule extended and allow us to explore the influence of applied force on torque and on molecule extension. The vertical force can be measured from the fluctuations of the probe in the x-y plane.13
An embodiment of a system for single molecule torque measurement according to the present invention is presented in
In an embodiment, the substrate 101 is glass, e.g., a glass capillary tube 123. However, the substrate can be formed of any other suitable material, such as a non-silica glass or a non-glass material.
The magnetic probe 109 formed from the magnetic bead 119 and the nanorod 121 is just one example of a magnetic probe 109 that can be used in an embodiment of a system according to the invention. For example, a magnetic probe 109 can include a single object, of which the second binding point 115 is offset from the magnetic moment 111. The magnetic probe 109 can have a nonspherical form and be aligned so that the imaging device can determine the azimuthal orientation of the magnetic probe 109. Alternatively, the magnetic probe can be marked (e.g., by a color or fluorescent marker) on different parts of its surface so that the imaging device can determine its azimuthal orientation even if its form appears symmetric (e.g., circular) to the imaging device.
The nanorod 121 can be formed of a nickel 1001 and a platinum 1003 segment as described (
The filament 105 under study can be, for example, a fiber, a structure containing multiple aligned macromolecules, a single DNA double helical structure having two polynucleotide strands, a single polynucleotide strand, or a single macromolecule, such as a polymer, or another structure, such as a carbon nanotube.
b presents a top view of the system. The horizontal force is symmetric around the axis of the cylindrical magnet 107 (broad arrows). The torque {right arrow over (L)}h×{right arrow over (F)}h orients the nanorod 121 in the direction of the force {right arrow over (F)}h 131. Controlled rotation of the magnetic probe 109 can be obtained by moving the glass capillary such that the probe follows a path around the projected center of the cylindrical magnet 107.
c presents a view of the system including the imaging device 117. A z-translational stage can move the cylindrical magnet 107 toward and away from the probe 109. Single molecule manipulation can take place inside a capillary tube 123 over an inverted optical microscope 125. Samples can be observed on an inverted microscope 125 (Nikon Eclipse, TE2000-E) using a 100× oil-immersion objective. The nosepiece of the microscope can be on a motorized z-stage which allows 50 nm steps. Video images can be obtained with a CCD digital camera 127 (Hamamatsu, ORCA-ER) connected to a PC computer. Video images can be analyzed in real time at 21 Hz using software written in MATLAB (version 7.6.0.324). The cylindrical magnet 107 can be held above the capillary by the z-translational linear stage.
Although
Controlled Introduction of Turns into the Molecule.
In an embodiment, we can introduce twist or turns into the molecule by rotating the probe attached to it. This can be done by using the features of the magnetic field created by the magnet 107 (for example, a cylindrical magnet) and the geometry of the magnetic probe, for example, the nanorod-bead probe shown in
The torque {right arrow over (L)}h×{right arrow over (F)}h, where {right arrow over (L)}h is the horizontal component of the distance between the DNA point of attachment to the probe (the second binding point 115) and the magnetic moment 111 (or magnetic center) of the probe, traps the fluctuations of the angle θ 113 and orients the magnetic probe 109 (for example, the nanorod 121 of the magnetic probe 109) in the direction of the force {right arrow over (F)}h (131). That is, the second binding point 115 is offset from (does not lie on) a line extending to infinity that passes through the vector defining the magnetic moment 111. We use this alignment of the nanorod 121 with {right arrow over (F)}h (131) to rotate the magnetic probe 109. The force {right arrow over (F)}h (131) points outwards, away from the axis of symmetry of a cylindrical magnet 107 and is symmetric around this axis (
Movement of the first binding point 103 relative to where the magnetic axis of the magnetic field (for example, the magnetic axis being where the horizontal force {right arrow over (F)}h is zero) intersects the substrate 101 (the magnetic axis intersection point) and/or consequent rotation of the magnetic probe 109 can be described by a winding number. For example, moving the first binding point 103 one turn counterclockwise in a closed path about the magnetic axis intersection point, while keeping the distance between the first binding point 103 and the intersection point sufficiently large so that the horizontal force {right arrow over (F)}h is great enough to rotate the magnetic probe 109 increases the winding number by one. Moving the first binding point 103 one turn clockwise in a closed path about the magnetic axis intersection point can decrease the winding number by one. The winding number can be fractional (e.g., 0.5 for one-half of a turn; 1.5 for one and one-half turns) when the angle traced by the line that joins the first binding point and the magnetic axis intersection point is not a multiple of 360 degrees.
The movement of the first binding point 103 relative to the magnetic axis intersection point to rotate the magnetic probe 109 can be achieved by holding the magnet 107 and/or the magnetic field it generates stationary and moving the first binding point 103 (for example, by moving the substrate 101). The curve traced by the first binding point 103 can be closed in some embodiments or open (for example, having the form of a spiral) in other embodiments to achieve a fractional or integer winding number of less than one, one, or greater than one. Alternatively, the movement of the first binding point 103 relative to the magnetic axis intersection point can be achieved by moving the magnet 107 and/or the magnetic field it generates and holding the first binding point 103 stationary (for example, by holding the substrate 101 stationary). The curve traced by the magnetic axis intersection point can be closed in some embodiments or open in other embodiments. Alternatively, the movement of the first binding point 103 relative to the magnetic axis intersection point can be achieved by moving the magnet 107 and/or the magnetic field it generates and moving the first binding point 103 relative to each other. The curve traced by either of the first binding point 103 and/or the magnetic axis intersection point can be closed in some embodiments or open in other embodiments.
For example, precise movement of the magnetic probe 109 can be facilitated by a manually or motor actuated stage, for example, a 2 axis motorized stage (H117 Proscan, Prior Scientific, Rockland, Mass., US). For example, the stage can be attached to the substrate 101 to move the first binding point 103. Alternatively, the stage can be attached to the magnet 107 (for example, a permanent magnet or an electromagnet) to move the magnetic axis intersection point. In the case of a cylindrical magnet 107, the magnetic axis can be approximately collinear with the geometric axis of the cylindrical magnet 107. Alternatively, other configurations can be used to move the magnetic axis intersection point and the first binding point 103 relative to each other, for example, one or more electromagnets can be used to move the magnetic field and the magnetic axis intersection point by varying electrical current delivered to the coil(s) of the electromagnet(s) without physically moving the magnet(s). After rotating to a desired configuration, the probe can be returned to the initial position with 2 pixels precision (88 nm) using a separate immobilized bead adhered to the glass surface as a reference.
Torque Measurement.
In an embodiment, we measure torque from the horizontal (azimuthal) angular fluctuations of the magnetic probe 109 attached to the molecule 105, before and after introducing turns into the molecule 105. The probe azimuthal angle or orientation θ (113) can result from the torque of the angular trap from the magnetic field and the resistive torque from the twisted molecule 105. Measurement of molecular torque can be achieved by confinement of the magnetic probe 109 in a weak angular trap such that the change in the in angular distribution due to the resistive torque is large enough to be measured. The torque {right arrow over (L)}h×{right arrow over (F)}h from the magnetic field traps the fluctuations of the horizontal (azimuthal) angle of the probe (θ) (113). The angular trap stiffness (kθ) is ≈|{right arrow over (L)}h∥{right arrow over (F)}h| and therefore, is determined by the point of attachment of DNA (second binding point 115) to the magnetic probe 109 (for example, to the nanorod 121) and by the position of the magnetic probe 109 in the magnetic field (see
Thus, the experiment presented in
Magnetic probes 109 can have, for example, |{right arrow over (L)}h| between 0.3 and 1 μm; and we position the magnetic probes 109 at <50 μm (for example, 40 μm) from the projected center of the cylindrical magnet 107, such that |{right arrow over (F)}h|<0.1 pN. The horizontal (azimuthal) angular trap generated by the torque {right arrow over (L)}h×{right arrow over (F)}h has, in these conditions, kθ as low as 30 pN·nm. By contrast, in the conventional magnetic tweezers configuration the horizontal magnetic field generated by two magnets, tightly constrains the horizontal angular movements of the probe, producing an angular trap stiffness 80 times higher (see
To obtain the configuration shown in
The magnetic attraction between the ferromagnetic Ni segment 1001 and the magnetic dipole that it induces in a superparamagnetic bead 119 results in self-assembly, as illustrated in
In contrast to a random attachment of a nonmagnetic particle to a magnetic bead, the attachment driven by the ferromagnetic Ni segment 1001 of the nanorod 121 produces a uniform population of magnetic probes 109 with the desired configuration (see
a presents a bright-field image of a nanorod-bead magnetic probe 109 (bar=1 μm). The probe is tethered to a glass substrate 101 by a DNA molecule 105 and pulled with a vertical magnetic field. The asymmetry of the magnetic probe 109 allows for precise angular measurement by an imaging device 117.
The torque at n number of turns can be obtained from two angular histograms, because angular fluctuations of the nanorod-bead magnetic probe 109 attached to a filament 105 or fiber report on the torque experienced by the magnetic probe 109. The net potential energy of the magnetic probe 109 is a combination of the forces from the imposed magnetic field and the elasticity of the molecule as a function of the probe azimuthal angle 113:
U=UB(θ)+E(θ)
where UB(θ) is the potential energy of the magnetic probe 109 in the magnetic field. E is the elastic energy of the molecule 105 as a function of the attached probe angle. Note that UB(θ) is a periodic function of θ (period=2π), but E is not. The angular fluctuation of the probe is given by the Boltzmann distribution
P(θ)∝e−U/k
To obtain torque at n turns of the molecule (θ=2πn), the angular histogram P0(θ) of the nanorod-bead magnetic probe 109 is first obtained before introducing turns into the molecule (n=0). P0(θ) describes the angular probability distribution of the magnetic probe 109 in the absence of resistive torque from the molecule 105. We fix the θ axis such that θ=0 in the P0(θ) distribution. Then, by moving the stage, we introduce n turns into the molecule 105 (see
where En(θ) is the elastic energy in the vicinity of 2πn. The second term of this expression is the resistive torque applied by the molecule 105 to the magnetic probe 109 at n turns (−τn).
The resistive torque of the molecule 105 can be estimated by approximating the angular trap of the field as a harmonic potential well. Approximating the magnetic contribution by a quadratic function (harmonic approximation) U0+kθθ2/2, we have θ=θ*, we obtain,
τn=kθθ
kθ is calculated from the mean square deviation of θ distribution, kBT/δθ2. Thus, the trap stiffness kθ multiplied by the change in the average angle between Pn(θ) and P0(θ) gives the torque at n turns. Trap stiffness (kθ=kBT/<δθ2>) is 34.5, 35.5 and 35.1 pN·nm at 0, −40, +45 turns respectively. The angle measurements shown in
Torque can also be obtained from Pn(θ) and P0(θ) without approximating the magnetic angular trap as a harmonic potential. The ratio of angular distributions is
The contribution of the magnetic field has been canceled out. At low pulling forces and n=0,E0(θ) is essentially a constant function and the molecular torque is zero. Thus, the elastic free energy of the molecule can be obtained from the log of the distributions ratio:
The molecular torque at n turns is the slope of the free energy, or
τn can be obtained by fitting a straight line to the log of the distributions ratio. The difference between torque values obtained with and without the harmonic approximation is less than 1.5 pN·nm and typically less than 0.5 pN·nm (data not shown).
Torque measurements can be made with the angular trap from the magnetic field not changing after turns are introduced into the molecule. We test this by calculating kθ at different number of turns. No significant change in kθ is observed associated with the change in θ or with the change in the z position of the magnetic probe 109 (
θ for curve at 0.6 pN in FIG. 4.
θ
θ
The observed stability of kθ is a consequence of the horizontal force being constant for z changes in the scale of the experiment and the nanorod 121 being highly constrained to the horizontal plane. Multiple torque measurements in two different DNA molecules 105 give a standard deviation of 0.8 pN·nm or less (see
The torque required to change the orientation of the magnetic probe 109 by the minimum detectable angle gives the torque resolution of the instrument. The nanorods 121 allow detection of ˜1° change. The horizontal angular trap imposed on the nanorod-bead magnetic probe 109 by the cylindrical magnet 107 can be approximated to the harmonic potential (See FIG. S3):
The torque τ required to displace the minimum of the potential energy by an angle θ* is kθθ*. We use magnetic probes 109 with trap stiffness (kθ) between 30 and 70 pN·nm and we can detect ˜2π/360 radians change. Thus, an embodiment of a system or instrument according to the present invention has a theoretical torque resolution of kθ (2π/360) (between 0.5 and 1.2 pN·nm). The potential that traps the horizontal angular fluctuations in conventional magnetic tweezers, where magnetic field and probe dipole are horizontal, is:
where C is a constant that depends on the level of magnetic saturation of the probe. In this case, kθ=CmB. This angular trap is significantly stiffer than the one generated by the system composed by cylindrical magnet 107 and nanorod-bead magnetic probe 109. The minimum kθ that we find for the conventional magnetic tweezers configurations that we tested was 2,300 pN·nm (FIG. S4). With this stiffness the instrument has resolution of 2,300 pN·nm (2π/360)=40 pN·nm.
Molecule Extension.
Molecule (or filament) extension can be measured from the interference pattern of the bead.24 This method allows us to measure molecule extension with <50 nm precision. The z-coordinate of the center of the bead 119 of the nanorod-bead magnetic probe 109 can be obtained by finding the best match of the bead interference profile in a calibration profile set. The profile set can be obtained at increasing distances from the objective with 50 nm steps using the motorized z-stage.27 Stage drift can be corrected by parallel tracking of the z-coordinate of a separate bead stuck to the bottom of the capillary tube.
We can calculate vertical pulling force in each of our torque measurements from the x and y fluctuation of the DNA point of attachment to the magnetic probe 109 (second binding point 115).2 Each degree of freedom of the magnetic probe has an average energy kBT which allows us to obtain the force as
where l is the vertical distance between the attachment point (first binding point 103) of the molecule 105 to the glass substrate 101 and the attachment point (second binding point 115) of the molecule 105 to the probe 109 (z-coordinate of the center of the bead 119). In our case, x is the coordinate of the DNA point of attachment (second binding point 115) at the nanorod 121. Since the nanorods 121 are fully covered with Neutravidin we do not know this position, but we can calculate it from the fluctuations of the probe. The DNA binding point is the center of rotation of the object. This point does not rotate, so it is the point along the axis of the probe that minimizes <δx2>. It is in the range 0.3-1 μm away from the magnetic section of the nanorod 121 (which coincides with the center of the bead 119 in the image) in the magnetic probes 109 we use.
The system cylindrical magnet 107 and nanorod-bead magnetic probe 109 can apply forces between 0.1 pN and 1.5 pN using 1 μm diameter beads 119. Larger beads (2.8 μm) are expected to generate vertical pulling forces of up to 10 pN.
Pulling (Elongational) Force.
The vertical gradient of the magnetic field produces a vertical pulling force. For example, changing the distance between the cylindrical magnet 107 and the glass substrate 101 in a 1 mm range allows adjustment of this force between about 0.1 and about 1.5 pN. The magnetic probes 109 are tethered to DNA or chromatin 105, and the vertical pulling force is computed from the fluctuations of the x-y position of the point along the nanorod where the DNA is attached.13
Probe Assembly.
The experiment is performed inside a capillary tube 123 over an inverted microscope 125 as shown in
Measurements.
We use the nanorod-bead magnetic probes 109 and the cylindrical magnet 107 configuration to track the motions of single 10 kb DNA molecules 105. The nanorod-bead magnetic probes 109 allow simultaneous tracking of horizontal angular fluctuations (torque), molecule extension, and pulling force. Results of single-molecule torque measurement of DNA at low pulling force are shown in
Our measurements for DNA extension and resistive torque as a function of turns agree with and extend previously published observations.9,11,12 Positive rotations (to overwind DNA) and negative rotations (to unwind DNA) are introduced into the DNA at pulling forces between 0.3-1.4 pN. For pulling forces of 0.6 and 1.4 pN, the torque is a linear function for low number of rotations. The linear behavior is interrupted at ≈−20 turns, corresponding to a ratio between the turns introduced in the molecule 105 and the molecule intrinsic number of helix turns of ≈−0.02. As more negative turns are introduced, melting of the duplex DNA occurs,13 and the torque is constant at −10 pN·nm. A similar value (−9.6 pN·nm) was obtained by Bryant et al. at pulling forces of 15 pN and 45 pN.12 At 0.3 pN and higher pulling forces, the linear behavior of the torque curve is also interrupted at positive turns. The exact number of rotations at which this happened is force-dependent and coincides with the buckling transition where plectonemic DNA started to form. The torque remains flat after DNA buckling (post-buckling torque), which has been observed at pulling forces above 1 pN,9,10,12 and is consistent with a phase transition between extended and plectonemic DNA.26 The inset in
The resistive torque of chromatin fibers 105 has not been experimentally measured previously. We obtain turn-vs-extension and turn-vs-torque curves for chromatin at 0.3 pN vertical pulling force, which is sufficiently low to prevent DNA melting when it is twisted.
The turn-vs-extension and turn-vs-torque curves at 0.3 pN pulling force are shown for three molecules 105 in
Chromatin fibers 105 have previously been reported to display hysteresis in single molecule twist-extension experiments.16 We find that such a twist-extension hysteresis is also coupled with torque hysteresis. That is,
In summary, embodiments of the system and methods according to the present invention enable the measurement of torque on single biomolecules. A nanorod-bead magnetic probe 109 manipulated with a vertical magnetic field is a component for measuring resistive torque with pN·nm resolution. In parallel with torque, molecule extension and pulling forces can be precisely measured. For the first time, torque at a physiologically relevant low pulling force (<1 pN) has been measured in a single molecule experiment. Our method is simple, and does not require extensive calibration or feedback systems. The use of magnetic probes 109 produced by self assembled magnetic nanorods 121 and superparamagnetic beads 119 creates new possibilities for magnetic manipulation of single molecules 105.
The method for determining the torque on a filament 105 has been implemented in software. The software was written in Matlab using the image analysis, image acquisition, and signal analysis toolbox. The software allows for measuring the torque applied to the filament 105 from the difference in the angular distribution of the magnetic probe 109 attached to the filament 105 before and after turns are introduced in the filament. The software tracks the position of two objects in two independent video streams coming from the same video (e.g., CCD) camera 127: a magnetic probe 109 attached to the filament 105 and a reference bead attached to the bottom of a (e.g., glass) substrate 101. The position (x, y, z) of the magnetic probe 109 is corrected with the position (x, y, z) of the reference bead to account for drifts in the system. The (azimuthal) angle of the magnetic probe 109 is tracked at 21 Hz. Torque measurement can be made, for example, by obtaining angular distributions of about 6000 measurements, which can be obtained, for example, over about 5 minutes. The software can determine torque on the filament 105, extension of the filament, and applied vertical (elongational or pulling) force. Software can be integrated with a module to control the imposition of turns on the filament.
Capillary tubes 123, 2×0.2 mm ID (Vitrocom, Mountain Lake, N.J., USA) previously piranha cleaned, were incubated 8 hrs in anti-digoxigenin solution (PBS complemented with 0.2 mg/ml polyclonal anti-Digoxigenin, Roche, Indianapolis, Ind., USA) and 12 hrs in blocking solution (10 mM phosphate buffer complemented with 10 mg/ml acetylated BSA, Sigma, St Louis, Mo., USA; 0.1% Tween-20; 10 mM EDTA; 3 mM NaN3). Both incubations were performed at 37° C., and capillary tubes stored at 4° C.
The substrate 101 can be coated with a material other than anti-digoxigenin. One of skill in the art will select an appropriate coating material based on the material of which the substrate 101 is formed and the filament 105 to be examined, as well as other experimental considerations.
Nanorods 121 were prepared by electrodeposition into the 200 nm diameter pores of an aluminum oxide template membrane (Whatman, Springfield Mill, Kent, England).23,28 An 800 nm cooper film was evaporated onto one side of a membrane and used as the working electrode. The nanorods 121 were formed by filling the pores of the membrane by the deposited material. Three different metal segments were deposited by changing the electrolytic solution. An 8 μm copper sacrificial segment was deposited from 500 mM CuSO4 (pH=1.0) by running a charge of 7 coulombs at −160 mV. The platinum segment 1003 was produced by running a charge of 3 coulombs from a solution of 17 mM (NH4)2PtCl6 and 250 mM Na2HPO4 (pH=7.8) at −350 mV, producing a 1.7±0.4 μm long segment. Finally, the nickel segment 1001 was deposited from a solution of 500 mM NiSO4 and 670 mM boric acid (pH=3.8) by running 0.4 coulombs at −800 mV, producing a 0.09±0.03 μm long segment. Copper was etched in a copper etchant BTP bath (Transene, Danvers, Mass., USA) at 40° C. for 12 hrs, and Al2O3 was etched in a 2 M KOH bath at 65° C. for 8 hrs.
Nanorods 121 were functionalized by incubating them for 30 min in a 10 mM phosphate buffer complemented with 0.1 mg/ml Neutravidin tetramethylrhodamine conjugate (Invitrogen, Eugene, Oreg., USA) and 0.1% Tween-20. Shaking during the incubation prevented aggregation of nanorods 121. Treatment with rhodamine-labeled Neutravidin allowed the visualization of the nanorods 121 (
We tested the quality of Neutravidin coating by measuring the percentage of nanorods 121 that were able to introduce supercoils into the bound DNA molecule. We found that there were always some molecules in which rotation of the handle did not result in molecule shortening. This behavior can result from single attachment points around which the molecule can swivel, releasing the twists. Such attachments can result from nicks in the DNA, or due to single connections with the probe or the glass: if DNA is linked to one of the surfaces by just one biotin or digoxigenin link, then it can swivel around that link. We found that our Neutravidin-labeled nanorods 121 gave the same percentage of supercoiled DNA (˜70%) as commercially available Streptavidin-coated beads (Invitrogen), indicating that the surface density of Neutravidin nanorods was not a limiting factor.
Alternatively, a compound other than Neutravidin can be used to coat the nanorods 121 and/or magnetic probes 109. One of skill in the art will be able to select an appropriate coating material depending on the filament 105 to be examined and other experimental considerations.
We used the same DNA fragment for naked DNA and chromatin experiments. The DNA fragment was generated from ligation of three pieces: two 900 bp DNA fragments, produced by PCR, containing either biotin- or digoxigenin-labeled nucleotides; and a central 10 kb fragment containing a 35×208 basepair (bp) repeat tandem array of the 5S positioning sequence flanked by vector DNA (a gift of Jeffrey Hansen). To enrich the desired population of DNA constructs (the 10 kb fragment flanked by both biotin- and digoxigenin-labeled fragments), we employed restriction enzymes to yield compatible cohesive ends: the biotin- and digoxigenin-labeled fragments were digested with Nhe I, and the vector containing the central array was digested with Xba I. Ligation of these fragments was performed in the presence of the Xba I and Nhe I restriction enzymes, and the correct product was therefore not recleavable by these enzymes. Compounds other than biotin and/or digoxigenin can be used to label a filament 105 and attach the filament 105 to the magnetic probe 109 and the substrate 101. One of skill in the art will be able to select appropriate compound(s) for labeling the filament 105 based on the filament 105 to be investigated, the materials of which the magnetic probe 105 and the substrate 101 are formed, and other experimental considerations.
Wildtype histones H2A, H2B, H3, and H4 from Xenopus laevis were expressed, purified, and reconstituted into octamers.29 Chromatin was generated by depositing these histone octamers onto the functionalized DNA using the salt gradient dialysis technique.29 For the reconstitution, the ratio of DNA to histones was varied from 0.6:1 to 1.2:1. We examine the level of histone saturation using analytical ultracentrifugation.30,31 For the histone:DNA ratios of 1.0:1.0 and lower, the samples appear relatively homogeneous, with 80% of each sample sedimenting at 23 S (0.6:1 ratio), 47 S (0.8:1 ratio), 72 S (1.0:1 ratio). In contrast, the 1.2:1 ratio displayed aberrant sedimentation that precludes van Holde/Weischet analysis, and is likely due to oversaturation of the array (data not shown). Chromatin samples prepared at a histone:DNA ratios of 0.8:1.0 were used for magnetic tweezer manipulation. Individual fibers 105 differed significantly in the apparent number of nucleosomes (see
Solutions were introduced into a capillary tube 123 by filling a pipet tip attached to the capillary via tygon tubing, and then pulling the solution into the capillary tube with a syringe pump (Harvard Apparatus, 11 Plus, Holliston, Mass., US). During the experiment, the connecting tygon tubing was clamped off to isolate the system from the exterior. All the experiments were conducted in standard buffer (10 mM phosphate buffer with 0.1% Tween-20). Naked DNA molecules or chromatin fibers (50 ng/ml) 105 were incubated in the capillary tube for 10 min to allow digoxigenin-labeled DNA ends to interact with the anti-digoxigenin coated glass surface. Unbound DNA or chromatin was washed away by flowing 300 μl of standard buffer through the capillary 123. Finally, 1 μm diameter superparamagnetic beads 119 (Dynabeads MyOne, Tosylactivated, Invitrogen, Carlsbad, Calif., USA) and functionalized nanorods 121 were flowed into the capillary. The surface of the beads 119 was not activated. Beads 119 and nanorods 121 self assemble in the absence of an external magnetic field, by the attraction between the ferromagnetic Ni segment and the superparamagnetic bead 119. During assembly, the preferred dipole orientation of the bead 119 aligns with the Ni segment dipole, such that under the vertical magnetic field created by the cylindrical magnet, the dipole of the bead 119 and the dipole of the Ni segment 1001 are vertical while the axis of the nanorod 121 is horizontal. The probes were lifted by placing the capillary tube under the cylindrical magnet 107 which was held by a linear stage (460P-XYZ, Newport, Irvine, Calif., US) ˜2 mm above the capillary tube 123.
The embodiments illustrated and discussed in this specification are intended only to teach those skilled in the art the best way known to the inventors to make and use the invention. Nothing in this specification should be considered as limiting the scope of the present invention. All examples presented are representative and non-limiting. The above-described embodiments of the invention may be modified or varied, without departing from the invention, as appreciated by those skilled in the art in light of the above teachings. It is therefore to be understood that, within the scope of the claims and their equivalents, the invention may be practiced otherwise than as specifically described.
This application claims the benefit of U.S. Provisional Application No. 61/158,507, filed Mar. 9, 2009, and of U.S. Provisional Application No. 61/159,006, filed Mar. 10, 2009, which are hereby incorporated by reference in their entirety. The present invention pertains to the measurement of torque imposed on a filament, such as a single DNA macromolecule in a duplex or double-stranded helical configuration.
This invention was made with Government support under Grant No. CMS-0528296 awarded by the National Institutes of Health. The Government has certain rights in this invention.
Number | Name | Date | Kind |
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20100253328 | Celedon et al. | Oct 2010 | A1 |
Number | Date | Country | |
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20100253328 A1 | Oct 2010 | US |
Number | Date | Country | |
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61159006 | Mar 2009 | US | |
61158507 | Mar 2009 | US |