Real-time imaging of the reorientation mechanisms of YOYO-labelled DNA molecules during 90 degrees and 120 degrees pulsed field gel electrophoresis

DNA binding fluorescent proteins as single-molecule probes

DNA binding fluorescent proteins are useful probes for a broad range of biological applications.

A Tour de Force on the Double Helix: Exploiting DNA Mechanics To Study DNA-Based Molecular Machines

DNA is both a fundamental building block of life and a fascinating natural polymer. The advent of single-molecule manipulation tools made it possible to exert controlled force on individual DNA molecules and measure their mechanical response. Such investigations elucidated the elastic properties of DNA and revealed its distinctive structural configurations across force regimes. In the meantime, a detailed understanding of DNA mechanics laid the groundwork for single-molecule studies of DNA-binding proteins and DNA-processing enzymes that bend, stretch, and twist DNA. These studies shed new light on the metabolism and transactions of nucleic acids, which constitute a major part of the cell's operating system. Furthermore, the marriage of single-molecule fluorescence visualization and force manipulation has enabled researchers to directly correlate the applied tension to changes in the DNA structure and the behavior of DNA-templated complexes. Overall, experimental exploitation of DNA mechanics has been and will continue to be a unique and powerful strategy for understanding how molecular machineries recognize and modify the physical state of DNA to accomplish their biological functions.

Pulsed Field Gel Electrophoresis: Past, present, and future

Pulsed Field Gel Electrophoresis (PFGE) has been considered for many years the 'gold-standard' for characterizing many pathogenic organisms as well as for subtyping bacterial species causing infection outbreaks. This article reviews the basic principles of PFGE and it includes the main advantages and limitations of the different electrode configurations that have been used in PFGE equipment and their influence on the DNA electrophoretic separation. Remarkably, we summarize here the most relevant theoretical and practical aspects that we have learned for more than 20 years developing and using the miniaturized PFGE systems. We also discussed the theoretical aspects related to DNA migration in PFGE agarose gels. It served as the basis for simulating the DNA electrophoretic patterns in CHEF mini gels and mini-chambers during experimental design and optimization. A critical comparison between standard and miniaturized PFGE systems, as well as the enzymatic and non-enzymatic methods for intact immobilized DNA preparation, is provided throughout the review. The PFGE current applications, advantages, limitations and future challenges of the methodology are also discussed.

Shining a Spotlight on DNA: Single-Molecule Methods to Visualise DNA

The ability to watch single molecules of DNA has revolutionised how we study biological transactions concerning nucleic acids. Many strategies have been developed to manipulate DNA molecules to investigate mechanical properties, dynamics and protein–DNA interactions. Imaging methods using small molecules and protein-based probes to visualise DNA have propelled our understanding of complex biochemical reactions involving DNA. This review focuses on summarising some of the methodological developments made to visualise individual DNA molecules and discusses how these probes have been used in single-molecule biophysical assays.

A systematic evaluation of the role of crystalline order in nanoporous materials on DNA separation

The role of order within a porous separation matrix on the separation efficiency of DNA was studied systematically. DNA separation was based on a ratchet mechanism. Monodisperse colloidal suspensions of nanoparticles were used to fabricate highly ordered separation media with a hexagonal close-packed structure. Doping with a second particle size yielded structures with different degrees of disorder, depending upon the volume fraction of each particle size. Radial distribution functions and orientational order parameters were calculated from electron micrographs to characterize the scale of disorder. The peak separation distance, band broadening, and separation resolution of DNA molecules was quantified for each structure. DNA separation parameters using pulsed fields and the ratchet effect showed a strong dependence on order within the porous nanoparticle array. Ordered structures gave large separation distances, smaller band broadening and better resolution than highly disordered, nearly random, porous structures. The effect dominated these three parameters when compared to the effect of pore size. However, the effect of order on separation performance was not monotonic. A small, but statistically significant improvement was seen in structures with short range order compared to those with long range order.

DNA migration mechanism analyses for applications in capillary and microchip electrophoresis

In 2009, electrophoretically driven DNA separations in slab gels and capillaries have the sepia tones of an old-fashioned technology in the eyes of many, even while they remain ubiquitously used, fill a unique niche, and arguably have yet to reach their full potential. For comic relief, what is old becomes new again: agarose slab gel separations are used to prepare DNA samples for "next-gen" sequencing platforms (e.g. the Illumina and 454 machines) - dsDNA molecules within a certain size range are "cut out" of a gel and recovered for subsequent "massively parallel" pyrosequencing. In this review, we give a Barron lab perspective on how our comprehension of DNA migration mechanisms in electrophoresis has evolved, since the first reports of DNA separations by CE ( approximately 1989) until now, 20 years later. Fused-silica capillaries and borosilicate glass and plastic microchips quietly offer increasing capacities for fast (and even "ultra-fast"), efficient DNA separations. While the channel-by-channel scaling of both old and new electrophoresis platforms provides key flexibility, it requires each unique DNA sample to be prepared in its own micro or nanovolume. This Achilles' heel of electrophoresis technologies left an opening through which pooled sample, next-gen DNA sequencing technologies rushed. We shall see, over time, whether sharpening understanding of transitions in DNA migration modes in crosslinked gels, nanogel solutions, and uncrosslinked polymer solutions will allow electrophoretic DNA analysis technologies to flower again. Microchannel electrophoresis, after a quiet period of metamorphosis, may emerge sleeker and more powerful, to claim its own important niche applications.

Effect of the matrix on DNA electrophoretic mobility

DNA electrophoretic mobilities are highly dependent on the nature of the matrix in which the separation takes place. This review describes the effect of the matrix on DNA separations in agarose gels, polyacrylamide gels and solutions containing entangled linear polymers, correlating the electrophoretic mobilities with information obtained from other types of studies. DNA mobilities in various sieving media are determined by the interplay of three factors: the relative size of the DNA molecule with respect to the effective pore size of the matrix, the effect of the electric field on the matrix, and specific interactions of DNA with the matrix during electrophoresis.

Neutron-scattering probe of complexes of sodium dodecyl sulfate and serum albumin during polyacrylamide gel electrophoresis

Small-angle neutron scattering (SANS) is used to probe the conformation of SDS-BSA protein surfactant complexes during electrophoresis in cross-linked polyacrylamide gels. Contrast variation permits independent probing of the structure of protein-surfactant complexes with negligible scattering contributions from the polyacrylamide matrix. The conformation of the protein complexes in the gel is found to be independent of the electric fields that are applied in this work (10 V/cm). Furthermore, there are no signs of large-scale macromolecular orientation (anisotropy) in the scattering patterns. However, the scattering shows that there are significant interparticle correlations between the protein-surfactant complexes that are electrophoretically inserted into the gel. These interactions develop when the total concentration of protein in the gels reaches values that are larger than approximately 1 mg/mL. The correlations are due to molecular crowding in the small fraction of pores that are available for protein migration.

Confinement effects on electromigration of long DNA molecules in an ordered cavity array

Confinement effects on the electromigration of long dsDNA molecules in an array of well-ordered, molecular sized cavities interconnected by nanopores are described. The array was prepared by replicating the structure of a colloidal crystal of microspheres in a polymer matrix. Both conformation and mobility studies show that the electrophoretic behavior of large DNA molecules is distinct from that in gels and other microfabricated sieves, showing a peak in mobility versus electric field, and an inversion in the separation order with field strength. A simple model was proposed to interpret this unexpected observation qualitatively. We conclude that the molecular behavior of DNA can be modified by the combination of entropic effect and electric trapping as a consequence of both unique geometry and conductivity of this cavity array material. This approach provides insights for design and optimization of on-chip molecular sieving structures for rapid separation of long DNA molecules. It may lead to a promising material for manipulation and size fractionation of other biological macromolecules.

Electromigration of Single Molecules of DNA in a Crystalline Array of 300-nm Silica Colloids

The velocities and conformations of single DNA chains were probed as they electromigrated at varying electric field strength through a crystalline array of silica colloids. An optically transparent film consisting of 300-nm silica colloids was formed on glass as a transparent crystalline layer of 7 mum thickness with an effective pore size of 45 nm. The behaviors of individual lambda-DNA molecules (48,502 base pairs) electromigrating through this material were observed to be analogous to the behaviors of long DNA chains in electrophoresis gels, including chain extension, hooking of chains around the matrix, and hernia formation. The electrophoretic mobility of lambda-DNA in this dense, narrow-pore material is surprisingly high: 1.8 cm2/Vs at 10 V/cm, which is at least as high as for much wider-pore gels. Imaging of the single molecules revealed that higher field strength caused increased chain extension and increased mobility, which reached an apparent plateau just above 2.0 cm2/Vs at 200 V/cm. Pulsed, crossed electric fields of 200 V/cm at 120 degrees to one another were applied to the material. The DNA chains were observed by imaging to electromigrate in an orderly fashion, and the migration rate was found to be length-dependent. The results indicate that these thin, robust, self-assembling inorganic materials are interesting as possible alternatives to polymeric gels for higher speed electrophoresis.

The polarization of fluorescence of DNA stains depends on the incorporation density of the dye molecules

BACKGROUND

The fluorescence induced by polarized light sources, such as the lasers that are used in flow cytometry, is often polarized and anisotropic. In addition, most optical detector systems are sensitive to the direction of polarization. These two factors influence the accuracy of fluorescence intensity measurements. The intensity of two light sources can be compared only if all details of the direction and degree of polarization are known. In a previous study, we observed that fluorescence polarization might be modified by dye-dye interactions. This report further investigates the role of dye density in fluorescence polarization anisotropy.

METHODS

We measured the polarization distribution of samples stained with commonly used DNA dyes. To determine the role of fluorophore proximity, we compared the monomeric and a dimeric form of the DNA dyes ethidium bromide (EB), thiazole orange (TO), and oxazole yellow (YO).

RESULTS

In all dyes sampled, fluorescence polarization is less at high dye concentrations than at low concentrations. The monomeric dyes exhibit a higher degree of polarization than the dimeric dyes of the same species.

CONCLUSIONS

The polarization of fluorescence from DNA dyes is related to the density of incorporation into the DNA helix. Energy transfer between molecules that are in close proximity loosens the linkage between the excitation and emission dipoles, thereby reducing the degree of polarization of the emission.

Manipulation of a Large DNA Molecule using the Phase Transition

A conventional method of DNA sequencing can determine up to 1000 base pairs at one time. Therefore, long DNA should be cut into many short fragments that are suitable for DNA sequencing. Those fragments, however, lose their order information. If the fragments are prepared from the terminus of the long DNA, the reorganization process can be omitted. This process consists of following unit operations; manipulation of genomic DNA, fixation with a stretched form, cutting from the terminus, recovery and amplification. In these unit operations, manipulation and cutting of DNA are focused in this report. Globular transformation suppresses break down of long genome DNA and permits manipulation of large DNA. Because globular transition is reversible, the coiled DNA can be sequentially spun from the globular DNA like a spindle. Thespun DNA was successfully fixed on a glass surface in an arbitrary pattern. To prepare fragments from the stretched DNA molecule, a method to cut DNA moleculen was developed. Since most restriction enzyme requires magnesium ion for their activation, the restriction enzyme was successfully activated only when magnesium ion was electrochemically supplied.

Trapping of DNA by thermophoretic depletion and convection

Thermophoresis depletes DNA from a heated spot. We quantify for the first time the thermal diffusion constant D(T)=0.4x10(-8) cm(2)/s K for DNA, using fluorescent dyes and laser heating. For 5 kB DNA we extrapolate a 1000-fold depletion from a temperature difference of 50 K. Surprisingly, convection generated by the same heating can turn the depletion into trapping of DNA. Trapped DNA can form point geometries 20 microm in diameter with more than 1000-fold enhanced concentrations. The accumulation is driven only by temperature gradients and offers a new approach to biological microfluidics and replicating systems in prebiotic evolution.

Manipulation of globular DNA molecules for sizing and separation

Handling large DNA molecules, such as chromosomal DNA, has become necessary due to recent developments in genome science. However, large DNA molecules are fragile and easily broken by shear stress accompanying flow in solution. This fragility causes difficulties in the preparation and handling of large DNA molecules. This study demonstrates the transition of DNA from a coiled to a globular form, which is highly condensed. This state suppresses DNA fragmentation due to shear stress in solution. The transition enables large DNA molecules to undergo mechanical manipulation. We confirmed that the fluorescence intensity of stained globular DNA increases with increasing length, suggesting that the resistance of globular DNA to shear stress is the factor that allows analysis of large DNA by flow cytometry.

High performance DNA sequencing, and the detection of mutations and polymorphisms, on the Clipper sequencer

The Visible Genetics Clipper sequencer is a new platform for automated DNA sequencing which employs disposable MicroCel cassettes and 50 microm thick polyacrylamide gels. Two DNA ladders can be analyzed simultaneously in each of 16 lanes on a gel, after labeling with far-red absorbing dyes such as Cy5 and Cy5.5. This allows a simultaneous bidirectional sequencing of four templates. We have evaluated the Clipper sequencer, by cycle-sequencing of an M13 single-stranded DNA standard, and by coupled amplification and sequencing (CLIP) of reverse-transcribed human immunodeficiency virus (HIV-1) RNA standards and clinical patient samples. (i) Limitations of instrument. We have examined basic instrument parameters such as detector stability, background, digital sampling rate, and gain. With proper usage, the optical and electronic subsystems of the Clipper sequencer do not limit the data collection or sequence-determination processes. (ii) Limitations of gel performance. We have also examined the physics of DNA band separation on 50 microm thick MicroCel gels. We routinely obtain well-resolved sequence which can be base-called with 98.5% accuracy to position approximately 450 on an 11 cm gel, and to position approximately 900 on a 25 cm gel. Resolution on 5 and 11 cm gels ultimately is limited by a sharp decrease in spacing between adjacent bands, in the biased reptation separation regime. Fick's (thermal) diffusion appears to be of minor importance on 6 cm or 11 cm gels, but becomes an additional resolution-limiting factor on 25 cm gels. (iii) Limitations of enzymology. Template quality, primer nesting, choice of DNA polymerase, and choice between dye primers and dye terminators are key determinants of the ability to detect mutations and polymorphisms on the Clipper sequencer, as on other DNA sequencers. When CLIP is used with dye-labeled primers and a DNA polymerase of the F667Y, delta(5'--> 3' exo) class, we can routinely detect single-nucleotide mutations and polymorphisms over the 0.35-0.65 heterozygosity range. We present an example of detecting therapeutically relevant mutations in a clinical HIV-1 RNA isolate.

Trapping of megabase-sized DNA molecules during agarose gel electrophoresis

Megabase DNA molecules become trapped in agarose gels during electrophoresis if the electric field exceeds a few volts per cm. Fluorescence microscopy reveals that these molecules invariably arrest in U-shaped conformations. The field-vs.-size dependence for trapping indicates that a critical molecular tension is required for trapping. The size of unligated lambda-ladders, sheared during gel electrophoresis at a given field, coincides with the size of molecules trapped at that field, suggesting that both processes occur through nick melting near the vertex of the U-shape. Consistently, molecules nicked by exposure to UV radiation trap more readily than unexposed ones. The critical trapping tension at the vertex is estimated to be 15 pN, a force sufficient to melt nicks bent around gel fibers, and, according to our model, trap a molecule. Strategies to reduce molecular tension and avoid trapping are discussed.

Comparison of DNA migrations in two clamped homogeneous electric field chambers of different sizes. Relation between sample thickness and electrophoresis time

We present here a method to compare the mathematical descriptions of DNA migration per pulse as a function of pulse time. It is based on obtaining robust estimates and variances of DNA reorientation time, migration velocities during and after DNA reorientation; and on the statistical comparisons of these estimates. We demonstrated an equal description for the migration per pulse of each DNA molecule separated under identical conditions in clamped homogeneous electric field (CHEF) and miniCHEF chambers. However, miniCHEF resolved the patterns in shorter times, because it uses thinner samples. The relationship between sample thickness and CHEF run time is also presented.

Electrophoresis of long DNA molecules in linear polyacrylamide solutions

Electrophoresis of long DNA (T4 DNA; 166 kb, S. pombe chromosomal DNA; 3-6 Mb) in linear polyacrylamide solutions was investigated by fluorescence microscopy and capillary electrophoresis. In the past studies on electrophoresis of long DNA in a polymer solution, it was reported that DNA migrates in 'U-shape conformation'. We found that at higher polymer concentrations, the shape of the migrating DNA changes from U shape to linear shape ('I-shape conformation'). In the migration mode with the I-shape conformation, the DNA moves with almost constant velocity and constant shape. However, the migration velocity does depend on the DNA size, and it is possible to separate DNAs under this I-shape motion. Actually, Mb-sized DNAs are well separated within 5 min in the region for the I-shape motion by means of capillary electrophoresis with a DC field. Considering that it takes 20 h to separate Mb-sized DNAs by standard pulsed-field gel electrophoresis (PFGE), this results will be useful for the separation of giant DNAs.

Reorientation of large DNA molecules in concentrated polyacrylamide solution during crossed-field electrophoresis

Recently, we found that, in concentrated neutral solutions, DNA molecules migrate in linear conformation under steady electric field. In this paper, we report the conformational change of DNA during 120 degree crossed-field electrophoresis in the same polymer solution. We found that, in concentrated polyacrylamide solutions, the reorientation process of DNAs becomes simple: the DNA goes back along the previous track and the reorientation time is longer for larger DNA. Such a backtrack motion has been thought to be an essential motion for the separation of DNA fragments in pulsed field gel electrophoresis. We expect that this phenomenon is useful for a more efficient separation technique of large DNAs than the current pulsed field gel electrophoresis.

Purification and staining of intact yeast DNA chromosomes and real-time observation of their migration during gel electrophoresis

In the past few years, fluorescence microscopy has been used successfully to characterize the motion of intermediate-size DNA molecules (50-500 kbp) during steady- and pulsed-field gel electrophoresis. However, experimental difficulties had prevented the application of this technique to the direct observation of longer DNA chromosomes (1-2 Mbp). In the present study a particular procedure was followed for the purification and staining of chromosomal yeast DNA to protect it from shear forces. Also, a new highly fluorescent DNA-labelling dye, YOYO-1, was employed to improve brightness and contrast. Finally, the motion of such long DNA molecules (1-2 Mbp) was characterized under steady-field electrophoresis conditions. An accurate description of the molecular mechanisms of motion of such long molecules should provide the basis for a detailed analysis of the mechanisms responsible for DNA trapping.