Theory of linear dichroism of DNA and DNA-containing structures

Analysis has been made of the relationship between the dichroic ratio of DNA polymers and the orientation of their transition dipoles. The molecules may be aligned in a mechanical shear or electric field. The effect of the shear or electric field on the orientation factor has been shown. The results of dipole moments and their dependence on the strength of the electric field have been discussed. Higher orders of coiling, flat packing and their various combinations cause the optical and electrical dichroic ratio to change characteristically, so that the electric and optical anisotropy of DNA can be utilized to study the DNA arrangement in DNA-containing structures.     

Effects of Extremely Low Frequency (Elf) Electric Fields On Cell Growth and Dna Repair In Human Skin Fibroblasts

Abstract. A number of physical and chemical agents in the environment have been studied for their ability to induce or alter DNA repair mechanisms in human cells. We have investigated the effects of 60 Hz, 1000 V/cm electric fields on DNA repair in normal human fibroblasts in vitro. an examination was done on the ability of electric fields suspected to cause damage which could be repaired by thymine dimer excision and measurable by the bromodeoxyuridine photolysis assay. the thymine dimer assay with enzyme-sensitive site analysis was used to measure the cells' capacity for removing ultraviolet light (u.v.)-induced pyrimidine dimers; (i) during exposure to electric field 24 hr before U.V. irradiation; (ii) 24 hr after U.V. irradiation; and (iii) up to 48 hr continuously after U.V. irradiation. Cell growth and cell survival following electric field exposure were also studied. Within the limits of these experiments, it was found that exposure to such electric fields did not alter cell growth or survival, and no DNA repair or alteration in DNA excision repair capacity was observed as compared with unexposed control cultures.     

Effects of extremely low frequency (ELF) electric fields on cell growth and DNA repair in human skin fibroblasts

A number of physical and chemical agents in the environment have been studied for their ability to induce or alter DNA repair mechanisms in human cells. We have investigated the effects of 60 Hz, 1000 V/cm electric fields on DNA repair in normal human fibroblasts in vitro. An examination was done on the ability of electric fields suspected to cause damage which could be repaired by thymine dimer excision and measurable by the bromodeoxyuridine photolysis assay. The thymine dimer assay with enzyme-sensitive site analysis was used to measure the cells' capacity for removing ultraviolet light (u.v.)-induced pyrimidine dimers; during exposure to electric field 24 hr before u.v. irradiation; 24 hr after u.v. irradiation; and up to 48 hr continuously after u.v. irradiation. Cell growth and cell survival following electric field exposure were also studied. Within the limits of these experiments, it was found that exposure to such electric fields did not alter cell growth or survival, and no DNA repair or alteration in DNA excision repair capacity was observed as compared with unexposed control cultures.     

Protein and DNA reactions stimulated by electromagnetic fields

The stimulation of protein and DNA by electromagnetic fields (EMF) has been problematic because the fields do not appear to have sufficient energy to directly affect such large molecules. Studies with electric and magnetic fields in the extremely low-frequency range have shown that weak fields can cause charge movement. It has also been known for some time that redistribution of charges in large molecules can trigger conformational changes that are driven by large hydration energies. This review considers examples of direct effects of electric and magnetic fields on charge transfer, and structural changes driven by such changes. Conformational changes that arise from alterations in charge distribution play a key role in membrane transport proteins, including ion channels, and probably account for DNA stimulation to initiate protein synthesis. It appears likely that weak EMF can control and amplify biological processes through their effects on charge distribution.     

Plasmodium falciparum: analysis of chromosomes separated by contour-clamped homogenous electric fields

We have established improved conditions for separating the chromosomes of Plasmodium falciparum by pulsed field gradient gel electrophoresis (PFG) using a contour-clamped homogenous electric field (CHEF) apparatus. Thirteen clearly separable chromosomal bands were reproducibly isolated from the strain FCR3 and their sizes have been determined. Evidence that indicates one band may contain two chromosomes is presented. The relationship between the PFG separable DNA and the number of unique chromosomes in P. falciparum is considered. We have established a relationship between the maximum resolvable sizes of the chromosomes and the pulse times. The chromosomal location of twenty-seven P. falciparum DNA probes is also reported.     

Electrophoretic separation of S. pombe chromosomes in polyacrylamide solutions using a constant field

Previous electrophoretic separations of megabase (Mb) sized DNA have been achieved in pulsed electric fields, using agarose gel as a matrix. The present study demonstrates separations of Mb sized DNA due to a retardation of migration in proportion to the concentration of uncrosslinked polyacrylamide of 5 x 10(6) molecular weight, using a constant electric field. Potentially, the method should be applicable to large DNA in general, greatly reducing the instrumental complexity of such separations and rendering them compatible with capillary electrophoresis apparatus.     

Effect of pulsed and reversing electric fields on the orientation of linear and supercoiled DNA molecules in agarose gels

When linear or supercoiled DNA molecules are imbedded in agarose gels and subjected to electric fields, they become oriented in the gel matrix and give rise to an electric birefringence signal. The sign of the birefringence is negative, indicating that the DNA molecules are oriented parallel to the electric field lines. If the DNA molecules are larger than about 1.5 kilobase pairs, a delay is observed before the birefringence signal appears. This time lag, which is roughly independent of DNA molecular weight, decreases with increasing electric field strength. The field-free decay of the birefringence is much slower for the DNA molecules imbedded in agarose gels than observed in free solution, indicating that orientation in the gel is accompanied by stretching. Both linear and supercoiled molecules become stretched, although the apparent change in conformation is much less pronounced for supercoiled molecules. When the electric field is rapidly reversed in polarity, very little change in the birefringence signal is observed for linear or supercoiled DNAs if the equilibrium orientation (i.e., birefringence) had been reached before field reversal. Apparently, completely stretched, oriented DNA molecules are able to reverse their direction of migration with little or no loss of orientation. If the steady-state birefringence had not been reached before the field reversal, complicated orientation patterns are observed after field reversal. Very large, partially stretched DNA molecules exhibit a rapid decrease in orientation at field reversal. The rate of decrease of the birefringence signal in the reversing field is faster than the field-free decay of the birefringence and is approximately equal to the rate of orientation in the field (after the lag period).(ABSTRACT TRUNCATED AT 250 WORDS)     

Polarized fluorescence studies of electrically oriented DNA-dye solutions

Transient changes have been recorded in each of the four polarized components of fluorescence, when dilute solutions of dye-tagged DNA are subjected to short electric pulses. The directions of the absorption and emission transition moments, and hence of the plane of the dye molecules, relative to the DNA geometry have been estimated for eleven dyes. Data obtained for ethidium bromide and five acridine derivatives are consistent with the intercalation model generally accepted for these dyes. In addition, it is shown that neutral red, acridine red and probably auramine O also bind with their molecular planes essentially perpendicular to the long helical axis. The remaining two, hydroxystilbamidine and the bibenzimidazole derivative Hoechst 33258, give rise to effects which indicate that these molecules bind in such a manner that the absorption and emission transitions are closely associated with the grooves of the DNA helix.     

Interaction of chromosomal stains with DNA. An electrofluorescence study

A novel fluorescence procedure has been used to study the binding characteristics of DNA with three modern fluorochromes currently used in chromosome cytochemistry. The transient changes in the polarised components of fluorescence have been recorded for dye-tagged DNA solutions when subjected to short duration electric pulses. From these data, it has been inferred that, like ethidium bromide, berberine sulphate and quinacrine mustard both intercalate the DNA structure whilst the bi-benzimidazole derivative Hoechst 33258 binds with a distinctively different geometry, probably within the helical grooves.     

Electric shock-mediated transfection of cells. Characterization and optimization of electrical parameters.

The effect of various parameters on the electric shock-mediated permeabilization and transfection of CHO cells has been investigated. Up to 70% of the cells can be maintained transiently permeable to erythrosin B for periods of at least 1 h at 20 degrees C. Electrical conditions optimal for transient permeabilization were also optimal for efficient DNA transfection by pSV2neo. However, the DNA must be present during exposure to the electric field for efficient transformation. The same requirement existed for voltage-induced DNA toxicity. The results suggest that DNA moves into the cells by electrophoresis, not by simple diffusion. Based on these observations a simple, rapid procedure for optimizing the conditions for electric shock-mediated DNA transfer into cells has been developed.     

Nanostructured layers from DNA, DNA:AU, DNA:C60 clusters

The idea is requisite to coat DNA, DNA:Au, DNA:C60 clusters from water solution, which can be magnetic and electrical active in biosensor systems and to detect their functional properties by microwave techniques (). Our research has been focused on the application of I-V characteristics and surface microwave resonator methods to recognise and predict these molecular interactions based on primary structure and associated physic-chemical properties. In results we have actually shown that these molecular cluster layers on Si and Al2O3 substrates can conduct, switch electric current and respond on power of microwave (additives Au, C60, determine the conductivity of layers). We also aim to apply these Si and Al2O3 ships for Biochip.     

The kinetics of fluorescent DNA labeling using PCR with different Taq polymerases depends on the chemical structures of modified nucleotides

The kinetics of DNA labeling during PCR using six fluorescent derivatives of 2′-deoxyuridine 5′-triphosphate has been studied. These compounds differ in their chemical structure, total electric charge and the length of the linker between a dye and the C5 position of a pyrimidine base. The efficiency of the incorporation of the fluorescent derivatives into a growing DNA chain by four commercially available Taq DNA polymerases with 5′→3′ exonuclease and hot start activity has been determined using real-time PCR with a TaqMan probe and the subsequent electrophoretic analysis of the reaction products. Modified deoxyuridines with a total positive or negative charge of the chromophore were practically not incorporated by Taq polymerases during PCR. The modified deoxyuridines with a neutral charge of the chromophore were effectively incorporated into DNA. The extended length of the linker between the pyrimidine base and the chromophore led to a lower PCR inhibition and a more effective inclusion of modified nucleotides in the growing DNA chain. This fact can be explained by the reduced steric effects that were caused by the dye. As a result, the most promising combinations of fluorescently labeled nucleotide and Taq polymerase have been chosen for further use in fluorescent DNA labeling.     

5-Methylcytosine as a marker for the monitoring of DNA methylation

The extent of the DNA methylation of genomic DNA as well as the methylation pattern of many gene-regulatory areas are important aspects with regard to the state of genetic information, especially their expression. There is growing evidence that aberrant methylation is associated with many serious pathological consequences. As genetic research advances, many different approaches have been employed to determine the overall level of DNA methylation in a genome or to reveal the methylation state of particular nucleotide residues, starting from semiquantitative methods up to new and powerful techniques. In this paper, the currently employed techniques are reviewed both from the point of view of their relevance in genomic research and of their analytical application. The methods discussed include approaches based on chromatographic separation (thin-layer chromatography, high-performance liquid chromatography, affinity chromatography), separation in an electric field (capillary electrophoresis, gel electrophoresis in combination with methylation-sensitive restriction enzymes and/or specific sequencing protocols), and some other methodological procedures (mass spectrometry, methyl accepting capacity assay and immunoassays).     

Contour-clamped homogeneous electric field electrophoresis of Staphylococcus aureus

Contour-clamped homogeneous electric field (CHEF) electrophoresis is a technique of pulsed-field gel electrophoresis that enables the resolution of large fragments of DNA that cannot be resolved by conventional gel electrophoresis. The procedure involves the application of controlled electric fields that change direction at a predetermined angle to samples of DNA that have been embedded in an agarose gel matrix and digested with a restriction endonuclease. Adjustment of the electrophoresis conditions enables the separation of DNA fragments with lengths from 10 kilobases up to 9 megabases in a size-dependent manner in agarose gels. The banding patterns can be used for epidemiological typing, the separated DNA can be immobilized onto a membrane and used for genetic mapping, or individual fragments can be extracted and used for downstream genetic manipulations. The protocol requires specialized equipment and can be completed in a maximum of 7 days.     

Quantitative analysis of the three regimes of DNA electrophoresis in agarose gels

An extensive series of experiments has been performed to study the mobility of DNA fragments ranging in size from 2.0 to 48.5 kilobose pairs. By varying the agarose concentration in the gels and the electric field strength, three DNA electrophoresis regimes were clearly identified: the Ogston regime (small DNA fragments in large pores of agarose), the reptation regime without DNA chain stretching (small pores of agarose and weak electric fields), and the reptation regime with DNA chain stretching (small pores of agarose, strong electric fields, and large DNA fragments). Here we report on the experimental identification of these regimes and on the conditions governing the transition between each of them. The onset of reptation and of stretching of DNA chains in gel electrophoresis are described quantitatively for the first time, and a phase diagram for the dynamics of DNA during electrophoresis is presented.     

Electric Near-field Modulations of Charged Deoxyribonucleic Acid Nucleobases

Deoxyribonucleic acid (DNA) has been recently recognized as a promising material for nanophotonics due to its outstanding electro-optical tuning. Here using the realistic state-of-the-art quantum mechanical calculations, we carried out a systematic theoretical study on the electric near-field modulations of charged DNA nucleobases. Our results underline that electrical doping (the addition or removal of an electron) produces dramatic modulations to the electric near-field enhancements in the visible spectral range. Interestingly, electrical doping causes high-intensity electric near-field hotspot regions to emerge in the technologically relevant visible spectral range. Our results unveil electric near-field manipulation of DNA nucleobases, which might find applications in novel nanophotonic devices.

     

Numerical simulation of gel electrophoresis of DNA knots in weak and strong electric fields

Gel electrophoresis allows one to separate knotted DNA (nicked circular) of equal length according to the knot type. At low electric fields, complex knots, being more compact, drift faster than simpler knots. Recent experiments have shown that the drift velocity dependence on the knot type is inverted when changing from low to high electric fields. We present a computer simulation on a lattice of a closed, knotted, charged DNA chain drifting in an external electric field in a topologically restricted medium. Using a Monte Carlo algorithm, the dependence of the electrophoretic migration of the DNA molecules on the knot type and on the electric field intensity is investigated. The results are in qualitative and quantitative agreement with electrophoretic experiments done under conditions of low and high electric fields.     

Nucleosomes arrangement in chromatin

The spatial arrangement of nucleosomes in rat liver chromatin has been examined using the electric birefringence technique. All chromatin subunits studied (up to 9 consecutive nucleosomes) contain their full complement of the five histone types associated with about 200 base pairs repeat length DNA.     

The electromechanics of DNA in a synthetic nanopore

We have explored the electromechanical properties of DNA on a nanometer-length scale using an electric field to force single molecules through synthetic nanopores in ultrathin silicon nitride membranes. At low electric fields, E < 200 mV/10 nm, we observed that single-stranded DNA can permeate pores with a diameter >/=1.0 nm, whereas double-stranded DNA only permeates pores with a diameter >/=3 nm. For pores <3.0 nm diameter, we find a threshold for permeation of double-stranded DNA that depends on the electric field and pH. For a 2 nm diameter pore, the electric field threshold is approximately 3.1 V/10 nm at pH = 8.5; the threshold decreases as pH becomes more acidic or the diameter increases. Molecular dynamics indicates that the field threshold originates from a stretching transition in DNA that occurs under the force gradient in a nanopore. Lowering pH destabilizes the double helix, facilitating DNA translocation at lower fields.     

Electrophoretic karyotypes of Phaffia rhodozyma strains

Abstract Electrophoretic karyotypes of strains from the astaxanthin-producing yeast Phaffia rhodozyma have been established. Intact chromosomal DNA molecules released from protoplasts were separated by orthogonal field alternation gel electrophoresis (OFAGE) and contour clamped homogeneous electric field (CHEF). Both small and large chromosomal DNA molecules were resolved simultaneously by optimizing the running conditions. Electrophoretic karyotypes among the Phaffia isolates examined differed significantly. Seven to thirteen chromosomal bands, ranging in size from 0.83 Mb to 3.50 Mb, were resolved, giving total genome sizes of about 15.4 to 23.2 Mb. Ribosomal DNA has been assigned to chromosomal bands using a heterologous gene probe.