Ultra-thin-layer agarose gel electrophoresis II. Separation of DNA fragments on composite agarose-linear polymer matrices

The effect of hydrophilic linear polymer additives (non-cross-linked polyacrylamide, hydroxyethyl cellulose and polyethylene oxide) on the migration behavior of double stranded DNA molecules, ranging from 200-1000 base pairs, were studied in ultra-thin-layer agarose gel electrophoresis. The detection sensitivity was found to be less than 0.1 ng/band using To-Pro-3 fluorophore labeling and fiber optic bundle-based scanning detection system with a 640 nm red diode laser. Among the various polymers investigated, addition of linear polyacrylamide resulted in the best separation performance (steepest Ferguson plots), while composite gels with hydroxyethylcellulose and polyethylene oxide still exhibited adequate resolving power. Using the composite matrices of 1% agarose-linear polyacrylamide (0.5-3%), 1% agarose-hydroxyethylcellulose (0.2-1%) and 1% agarose-polyethylene oxide (0.2-1%), the mechanism of the separation was found to be in the Ogston sieving regime. Activation energy curves were also plotted based on the slopes of the Arrhenius plots of the various composite matrices, and exhibited decreasing characteristics for the agarose-linear polyacrylamide composite matrix and increasing characteristics for the agarose-hydroxyethylcellulose and agarose-polyethylene oxide composite matrices.     

Discontinuous buffer system for polyacrylamide and agarose gel electrophoresis of DNA fragments

DNA fragments up to 9 kb in size were stacked and separated by polyacrylamide gel electrophoresis, and those up to 50 kb in size by agarose gel electrophoresis, using a discontinuous buffer system. Polyacrylamide gels at pH 8.9, 2 degrees C, 0.01 M ionic strength, yielded sharp bands with DNA loads of 8 micrograms/cm2 of gel of a mixture of 19 DNA fragments in the size range of 72-23130 bp, while agarose gels at pH 8.5, 25 degrees C, provided well-resolved, unperturbed bands at 0.04 M ionic strength with DNA loads of 1 microgram/cm2 of the same mixture. Note that the ionic strength of the agarose gels is comparable to the conventionally used 0.5 x TBE (Tris-borate-EDTA) buffer, while that successfully applied to polyacrylamide is seven-fold less than the ionic strength of conventionally used 1 x TBE buffer, with a substantially shorter duration of electrophoresis as a result. The application of a discontinuous buffer system to the gel electrophoresis of DNA results in (i) Band identification by Rf, the migration distance relative to a sharply defined "buffer front" (moving boundary). This is sufficiently labor saving, compared to determining absolute mobilities, so as to render practical the expression of bands as numbers, with benefits for data storage, statistical manipulations and physico-chemical exploitation of mobility data. The use of Rf's also circumvents loss of precision in mobility measurement resulting from progressive band spreading of dye bands used as a front. (ii) A uniformly and highly concentrated starting zone, beneficial to resolution, is obtained, without the losses by which separate concentration steps are usually burdened.(ABSTRACT TRUNCATED AT 250 WORDS)     

基于微芯片电泳的脱氧核糖核酸片段的浓缩和分离

采用超负荷电动供给(electrokinetic supercharging, EKS)预浓缩技术,在微芯片电泳(MCE)上对脱氧核糖核酸（DNA）片段进行浓缩和分离。EKS是集合样品电动进样(EKI)和过渡等速电泳(tITP)的一种在线浓缩方法。研究表明：采用该方法后,在40.5 mm长的单通道芯片上能够实现对低浓度样品的大量进样、浓缩和基线分离。在普通的紫外检测条件(检测波长为260 nm)下,对DNA片段的平均检出限(S/N=3)约为0.07 mg/L,仅为十字芯片上的微芯片电泳检出限的1/40。本文还对浓缩过程中的一些关键因素和定性分析进行了探讨。     

Multiplasmid DNA in agarose gel electrophoresis: Suitable dye and temperature is essential for prominent profiles

Nucleic acids dye Goldview is widely used in agarose gel electrophoresis (AGE). However, in this study, a sample of multiplasmid DNA (multi-pDNA) stained with Goldview analyzed by AGE showed its instability at low temperature. Three types of DNA samples were analyzed, including linear DNA (ladder), single-plasmid DNA (single-pDNA), and multi-pDNA, electrophoretic conditions were optimized by adjusting the dye, the buffer, and the temperature (1–50°C). The results showed that the light intensity of Gelred is 2.2-times higher than that of Goldview in staining multi-pDNA. Compared with the single-pDNA and the linear DNA, the multi-pDNA stained with Goldview was greatly affected by temperature. This short communication indicated that Gelred is a highly applicable dye for analyzing multiplasmid samples. The degree and the way of binding of Goldview to multi-pDNA are greatly affected by temperature.     

Characterization of single-stranded DNA separation by capillary gel electrophoresis

We have investigated the effect of polymer gel reconditioning, the shape of the capillary, the applied electric field, and the capillary length for single-stranded DNA. The polyethylene oxide gel had deformed under the high electric field causing the degradation of the separation power. By the reintroduction of the fresh polyethylene oxide gel for the next run, one-base resolution was recovered. It turned out that the tip of the capillary at the injection side needed to be clean and symmetric for much improved resolution. Changing DNA motion by the pulsed electric field resulted in the separation of DNA far more than 500 bases.     

Band broadening of DNA fragments isolated by polyacrylamide gel electrophoresis in capillary electrophoresis

Polyacrylamide gel electrophoresis (PAGE) is used frequently for isolation and purification of DNA fragments. In the present study, DNA fragments extracted from polyacrylamide gels showed significant band broadening in capillary electrophoresis (CE). A pHY300PLK (a shuttle vector functioning in Escherichia coli and Bacillus subtilis) marker, which contained nine fragments ranging from 80 to 4870 bp, was separated by PAGE, and each fragment was isolated by phenol/chloroform extraction and ethanol precipitation. After extraction from the polyacrylamide gel, the peaks of the isolated DNA fragments exhibited band broadening in CE, where a linear poly(ethylene oxide) was used as a sieving matrix. The theoretical plate numbers of the DNA fragments contained in the pHY300PLK marker were >10⁶ for all the fragments before extraction. However, the DNA fragments extracted from the polyacrylamide gel showed decreased theoretical plate numbers (5–20 times smaller). The degradation of the theoretical plate number was significant for middle sizes of the DNA fragments ranging from 489 to 1360 bp, whereas the largest and smallest fragments (80 and 4870 bp) had no obvious influence. The band broadening was attributed to contamination of the DNA fragments by polyacrylamide fibers during the separation and extraction process.     

Sieving of double-stranded DNA during agarose gel electrophoresis

Agarose gel electrophoresis is used to fractionate linear, double-stranded DNA by its length. Sieving of the gel is the cause of this fractionation and has been investigated by developing theoretical models and by quantifying sieving observed during electrophoresis. Here are reviewed the following aspects of the fractionation of linear, double-stranded DNA by agarose gel electrophoresis: (1) the basic observations that qualitatively characterize these fractionations, (2) evidence for the deformation of DNA's random coil, (3) quantitative analysis of the relationship of observed electrophoretic mobility to the DNA's length, (4) theoretical models that have been developed to explain data presented in Sections 1-3, (5) observations not yet quantitatively explained by models, and (6) some aspects of the use of a variable electrical field (pulsed-field gel electrophoresis) to improve separations.     

DNA electrophoresis in agarose gels: effects of field and gel concentration on the exponential dependence of reciprocal mobility on DNA length

Electrophoretic mobilities of DNA molecules ranging in length from 200 to 48 502 base pairs (bp) were measured in agarose gels with concentrations T = 0.5% to 1.3% at electric fields from E = 0.71 to 5.0 V/cm. This broad data set determines a range of conditions over which the new interpolation equation nu(L) = (beta+alpha(1+exp(-L/gamma))(-1) can be used to relate mobility to length with high accuracy. Mobility data were fit with chi(2) > 0.999 for all gel concentrations and fields ranging from 2.5 to 5 V/cm, and for lower fields at low gel concentrations. Analyses using so-called reptation plots (Rousseau, J., Drouin, G., Slater, G. W., Phys. Rev. Lett. 1997, 79, 1945-1948) indicate that this simple exponential relation is obeyed well when there is a smooth transition from the Ogston sieving regime to the reptation regime with increasing DNA length. Deviations from this equation occur when DNA migration is hindered, apparently by entropic-trapping, which is favored at low fields and high gel concentrations in the ranges examined.     

Portable capillary electrophoresis system with potential gradient detection for separation of DNA fragments

A portable capillary electrophoresis (CE) system with a novel potential gradient detection (PGD) was utilized to separate DNA fragments. For the first time it was demonstrated that separation of DNA fragments in polymer solution could be detected by a portable CE system integrated with PGD, with a limit of detection (LOD) comparable to that of the CE-ultraviolet (UV) method. Effects of buffer solution, sieving medium, and applied voltage were also investigated. The portable CE-PGD system shows several potential advantages, such as simplicity, cost effectiveness, and miniaturization.     

High-sensitivity capillary gel electrophoretic analysis of DNA fragments on an electrophoresis microchip using electrokinetic injection with transient isotachophoretic preconcentration

The research adopted a single-channel microchip as the probe, and focused electrokinetic injection combined with transient isotachophoresis preconcentration technique on capillary electrophoresis microchip to improve the analytical sensitivity of DNA fragments. The channel length, channel width and channel depth of the used microchip were 40.5 mm, and 110 and 50 μm, respectively. The separation was detected by CCD (charge-coupled device) (effective LENGTH=25 mm, 260 nm). A 1/100 diluted sample (0.2 mg/l of each DNA fragment) of commercially available stepladder DNA sample could be baseline separated in 120 s with S/N=2–5. Compared with conventional chip gel electrophoresis, the proposed method is ideally suited to improve the sensitivity of DNA analysis by chip electrophoresis.     

Effect of temperature on the separation of long DNA fragments in polymer solution

Electrophoresis of long DNA fragments in polymer solutions is still attractive when performed in short capillaries. Then the separations can be accomplished in minutes rather than hours as is usual in various slab electrophoresis techniques. In this paper we focused on the behavior of large DNA fragments in pulsed field capillary electrophoresis under various temperature conditions. The mobility dependence of fragments of lambda-DNA single-cut mixture on various frequencies at three different temperatures showed that the antiresonance mobility minima are shifted to higher frequencies at higher temperatures. This interesting result is explained in terms of the geometration model of DNA motion.     

Distinction between supercoiled and linear DNA in transverse agarose pore gradient gel electrophoresis.

Four species of linear DNA and the first four members of a linking series, generated by treatment of plasmid DNA (PUC19, 2.7 kb) with mitochondrial topoisomerase I, were differentiated by transverse agarose pore gradient gel electrophoresis. The experimental curves of migration distance vs. agarose concentration (Ferguson curves) of supercoiled DNA exhibit a steeper trajectory than those of linear DNA of the same size range. As a consequence, the four supercoiled species exhibit an increase in apparent size (relative to linear DNA standards) with increasing agarose concentration. Both the crossing of the Ferguson curves with those of linear standards as well as the apparent size increase with agarose concentration can serve to detect supercoiled plasmid-sized DNA in mixtures with linear DNA.     

Glycerol-enhanced mini-polyacrylamide gel electrophoresis for the separation of differentially expressed DNA fragments in cDNA representational difference analysis

Representational difference analysis (RDA) is a widely used technique in molecular biology. However, in practice, its efficiency depends on a rapid and reliable separation of the RDA fragments prior to cloning. To achieve this, we have compared and combined the separation efficiencies of conventional and MetaPhor agarose gel electrophoresis (MAGE) with a glycerol-enhanced mini-polyacrylamide gel electrophoresis (PAGE) system (Gem-PAGE). As anticipated, MetaPhor agarose provided significantly improved resolution over conventional agarose electrophoresis, but the latter remains useful to rapidly confirm the presence of RDA-enriched difference products and direct the concentration of MetaPhor agarose subsequently used for further fragment separation. Additional improvements in resolution were possible by using the Gem-PAGE system. The effect of glycerol on band definition of PAGE was most noticeable as the acrylamide to glycerol ratio (A:G) approached 1:2. Gels in which the A:G ratio was significantly above or below this resulted in both poor morphology and impaired resolution of the bands. By exploiting sequentially agarose-based and Gem-PAGE electrophoresis, the goal in RDA of "one band one product" is now realizable.     

Simultaneous Ferguson plot analysis, using electrophoresis on a single agarose pore gradient gel, of DNA fragments contained in a mixture.

A recent study has demonstrated the feasibility of obtaining Ferguson plots in agarose gel electrophoresis, using a single pore gradient gel. We now report three remedies for defects in the previous experimental approach: (i) UV-absorbing media for density stabilization of the gel is avoided by replacing 5-(N-2,3-dihydroxypropylacetamido)-2,4,6-triiodo-N,N'-bis(2,3-dihy droxypropyl) isophthalamide (Nycodenz) with heavy water; this renders the method applicable to ethidium bromide-labeled DNA. (ii) The density stabilizing medium is kept from having an effect on field strength. (iii) Data collection by uninterrupted time-lapse photography is possible by using an apparatus with a quartz window. These three measures make the method practical for the gel electrophoretic identification and physical characterization of DNA species, potentially up to 50 kb in size.     

High-sensitive analysis of DNA fragments by capillary gel electrophoresis using transient isotachophoresis preconcentration and fluorescence detection

In this report aimed on further development of a high-sensitivity capillary gel electrophoresis (CGE) method for analysis of DNA fragments, we firstly explored online transient isotachophoresis (tITP) preconcentration combined with fluorescence detection (FD). The fluorescence signal (excitation: 488 nm; emission: 590 nm) was generated using the intercalating dye of ethidium bromide (EB). It was found when the leading electrolyte (LE) was injected behind the sample zone, such a special tITP mode has significant advantages to solve the bubble formation issue and to improve the analytical performance stability. Two standard DNA samples, a 50 bp DNA step ladder and the φX174/HaeIII digest, were used to evaluate the qualitative and quantitative abilities of the tITP-FD approach. A highly diluted sample (10,000-fold in the water, e.g. the φX174/HaeIII digest diluted from 500 μg/ml to the 50 ng/ml level) was enriched and detected; the LOD was down to 0.09 ng/ml for the 72 bp fragment, apparently improved more than 1000-fold in comparison with UV detection. Although the RSD of peak areas (n = 3) was around 15.5% for the sample was electrokinetically injected, good linearity of peak area response showed that the proposed method is suitable for quantitative analysis.     

Capillary gel electrophoresis of single-stranded DNA fragments with UV detection

Capillary gel electrophoresis has proven to be a powerful tool in biomedical research. We report our investigation of some of the critical parameters affecting separations of single-stranded DNA fragments as monitored by ultraviolet (UV) absorbance detection. Although not as sensitive as laser-induced fluorescence (LIF), UV absorbance detection allows one to calculate quite accurately, and inexpensively, the molarity of each separated DNA fragment and, moreover, the signal “fading” effect normally observed with LIF detection can be, in many cases, substituted for fluorescence to detect the many different single-stranded DNAs, as well as for detection of sequencing reactions.     

Single-molecule measurements of trapped and migrating circular DNA during electrophoresis in agarose gels

The effect of agarose gel concentration and field strength on the electrophoretic trapping of open (relaxed) circular DNA was investigated using microscopic measurements of individual molecules stained with a fluorescent dye. Three open circles with sizes of 52.5, 115, and 220 kbp were trapped by the electric field (6 V/cm) and found to be predominately fixed and stretched at a single point in the gel. The length of the stretched circles did not significantly change with agarose concentration of the gels (mass fractions of 0.0025, 0.01, and 0.02). The relaxation kinetics of the trapped circles was also measured in the gels. The relaxation of the large open circles was found to be a slow process, taking several seconds. The velocity and average length of the 52.5 kbp open circles and 48.5 kbp linear DNA were measured during electrophoresis in the agarose gels. The velocity increased when the agarose concentrations were lowered, but the average length of the open-circle DNA (during electrophoresis) did not significantly change with agarose gel concentrations. The circles move through the gels by cycles of stretching and relaxation during electrophoresis. Linear dichroism was also used to investigate the trapping and alignment of the 52.5 kbp open circles. The results in this study provide information that can be used to improve electrophoretic separations of circular DNA, an important form of genetic material and commonly used to clone DNA.