Modification of gel architecture and TBE/TAE buffer composition to minimize heating during agarose gel electrophoresis

Agarose gel electrophoresis of DNA and RNA is routinely performed using buffers containing either Tris, acetate, and EDTA (TAE) or Tris, borate, and EDTA (TBE). Gels are run at a low, constant voltage (∼10 V/cm) to minimize current and asymmetric heating effects, which can induce band artifacts and poor resolution. In this study, alterations of gel structure and conductive media composition were analyzed to identify factors causing higher electrical currents during horizontal slab gel electrophoresis. Current was reduced when thinner gels and smaller chamber buffer volumes were used, but was not influenced by agarose concentration or the presence of ethidium bromide. Current was strongly dependent on the amount and type of EDTA used and on the concentrations of the major acid–base components of each buffer. Interestingly, resolution and the mobilities of circular versus linear plasmid DNAs were also affected by the chemical form and amount of EDTA. With appropriate modifications to gel structure and buffer constituents, electrophoresis could be performed at high voltages (20–25 V/cm), reducing run times by up to 3-fold. The most striking improvements were observed with small DNAs and RNAs (10–100 bp): high voltages and short run times produced sharper bands and higher resolution.     

Cost‐effective media for the rapid and high resolution of small DNA fragments using polyacrylamide‐based electrophoresis

Current Tris‐based solutions for DNA electrophoresis produce a positive feedback loop between current and temperature at high voltage, resulting in long running times for the separation of even small DNA fragments. We optimized the separation of small DNA fragments (90–300 bp) in polyacrylamide‐based electrophoresis at high voltages (200volts/cm) by substituting Tris with low concentration alkali salts (e.g. 1 mm LiCl and CsCl). These media reduced the heat produced during electrophoresis, enhanced the DNA fragment resolution, and allowed gels to be run at higher voltages, reducing gel running times by 25%. In addition, the elimination of Tris and EDTA from the buffer reduced material costs approximately 10‐fold.     

A small (58-nm) attached sphere perturbs the sieving of 40-80-kilobase DNA in 0.2-2.5% agarose gels: analysis of bacteriophage T7 capsid-DNA complexes by use of pulsed field electrophoresis.

Although the icosahedral bacteriophage T7 capsid has a diameter (58 nm) that is 234-fold smaller than the length of the linear, double-stranded T7 DNA, binding of a T7 capsid to T7 DNA is found here to have dramatic effects on the migration of the DNA during both pulsed field agarose gel electrophoresis (PFGE; the field inversion mode is used) and constant field agarose gel electrophoresis (CFGE). For these studies, capsid-DNA complexes were obtained by expelling DNA from mature bacteriophage T7; this procedure yields DNA with capsids bound at a variable position on the DNA. When subjected to CFGE at 2-6 V/cm in 0.20-2.5% agarose gels, capsid-DNA complexes arrest at the electrophoretic origin. Progressively lowering the electrical potential gradient to 0.5 V/cm results in migration; most complexes form a single band. The elevated electrical potential gradient (3 V/cm) induced arrest of capsid-DNA complexes is reversed when PFGE is used instead of CFGE. For some conditions of PFGE, the mobility of capsid-DNA complexes is a function of the position of the capsid on the DNA. During either CFGE (0.5 V/cm) or PFGE, capsid-DNA complexes increasingly separate from capsid-free DNA as the percentage of agarose increases. During these studies, capsid-DNA complexes are identified by electron microscopy of enzymatically-digested pieces of agarose gel; this is apparently the first successful electron microscopy of DNA from an agarose gel.(ABSTRACT TRUNCATED AT 250 WORDS)     

Improved resolution of DNA fragments in polysaccharide-supplemented agarose gels

The electrophoretic separation of nucleic acids, including small DNA fragments in the range 50-1000 bp, is presently carried out in polyacrylamide gels or in gels containing high concentrations of agarose. We have developed an alternative gel matrix composition which is inexpensive, nontoxic, easy to prepare, and highly transparent to visible and uv light. The composition combines a soluble nonionic polysaccharide such as hydroxyethylcellulose, methylcellulose, or galactomannan with a minimum but sufficient concentration of agarose to form a gel which immobilizes the "liquid phase sieve." These mixtures do not replace polyacrylamide for resolving fragments smaller than approximately 75 nucleotides. However, the new gels show DNA fragment resolution (band separation versus distance traveled) and optical clarity superior to those of conventional agarose.     

GelStar nucleic acid gel stain: high sensitivity detection in gels.

GelStar nucleic acid gel stain can be used for sensitive fluorescent detection of both double-stranded (ds) and single-stranded (ss) DNAs, oligonucleotides and RNA in gels. The stain can be added to agarose gels at casting for immediate imaging after electrophoresis or can be used after electrophoresis with both agarose and acrylamide gels. GelStar stain is highly fluorescent only when bound to nucleic acids thus giving superior signal-to-noise ratios and obviating the need to destain the gel. The detection limits of GelStar strain are 20 pg for dsDNA, 25 pg for ssDNA and 10 ng for native or glyoxal-treated RNA.     

Agarose and polyacrylamide gel electrophoresis methods for molecular mass analysis of 5- to 500-kDa hyaluronan

Agarose and polyacrylamide gel electrophoresis systems for the molecular mass-dependent separation of hyaluronan (HA) in the size range of approximately 5–500 kDa were investigated. For agarose-based systems, the suitability of different agarose types, agarose concentrations, and buffer systems was determined. Using chemoenzymatically synthesized HA standards of low polydispersity, the molecular mass range was determined for each gel composition over which the relationship between HA mobility and logarithm of the molecular mass was linear. Excellent linear calibration was obtained for HA molecular mass as low as approximately 9 kDa in agarose gels. For higher resolution separation, and for extension to molecular masses as low as approximately 5 kDa, gradient polyacrylamide gels were superior. Densitometric scanning of stained gels allowed analysis of the range of molecular masses present in a sample as well as calculation of weight-average and number-average values. The methods were validated for polydisperse HA samples with viscosity-average molecular masses of 112, 59, 37, and 22 kDa at sample loads of 0.5 μg (for polyacrylamide) to 2.5 μg (for agarose). Use of the methods for electrophoretic mobility shift assays was demonstrated for binding of the HA-binding region of aggrecan (recombinant human aggrecan G1–IGD–G2 domains) to a 150-kDa HA standard.     

A vertical submarine electrophoresis apparatus for polyacrylamide minigels

A vertical submarine electrophoresis apparatus for use with minislab polyacrylamide gels is described. The design allows polyacrylamide gels to be run with the same ease and convenience that agarose gels are run with horizontal submarine apparatuses. The vertical submarine features a single buffer chamber with a restriction between the upper and the lower portions of the chamber. Acrylamide gels, cast between 9 X 10-cm glass slides, are inserted into the restriction and are completely immersed in buffer. Thus, current flows primarily through the gel itself, but some current flows through the buffer in the restriction surrounding the gel. Because water-tight separation of buffer chambers is not necessary, time-consuming and/or expensive procedures such as sealing with agarose or using fragile notched glass plates are eliminated. The apparatus can be set up to run a gel in less than 30 s. It is versatile in that gels of varying thickness (0.5, 0.8, 1.5, and 3 mm) can be run on a single apparatus. The apparatus has been used for sodium dodecyl sulfate gels, low ionic strength native gels for nucleoprotein complexes, and composite acrylamide-agarose gels.     

Manual 768 or 384 well microplate gel ‘dry’ electrophoresis for PCR checking and SNP genotyping

Electrophoresis continues to be a mainstay in molecular genetic laboratories for checking, sizing and separating both PCR products, nucleic acids derived from in vivo or in vitro sources and nucleic acid–protein complexes. Many genomic and genetic applications demand high throughput, such as the checking of amplification products from many loci, from many clones, from many cell lines or from many individuals at once. These applications include microarray resource development and expression analysis, genome mapping, library and DNA bank screening, mutagenesis experiments and single nucleotide polymorphism (SNP) genotyping. PCR hardware compatible with industry standard 96 and 384 well microplates is commonplace. We have previously described a simple system for submerged horizontal 96 and 192 well polyacrylamide or agarose microplate array diagonal gel electrophoresis (MADGE) which is microplate compatible and suitable for PCR checking, SNP typing (restriction fragment length polymorphism or amplification refractory mutation system), microsatellite sizing and identification of unknown mutations. By substantial redesign of format and operations, we have derived an efficient ‘dry’ gel system that enables direct 96 pin manual transfer from PCR or other reactions in microplates, into 768 or 384 well gels. Combined with direct electrode contact in clamshell electrophoresis boxes which plug directly to contacts in a powered stacking frame and using 5–10 min electrophoresis times, it would be possible (given a sufficient supply of PCRs for examination) for 1 million gel tracks to be run per day for a minimal hardware investment and at minimal reagent costs. Applications of this system for PCR checking and SNP genotyping are illustrated.     

Molecular sequestration stabilizes CAP-DNA complexes during polyacrylamide gel electrophoresis.

The gel electrophoresis mobility shift assay is widely used for qualitative and quantitative characterization of protein complexes with nucleic acids. Often it is found that complexes that are short-lived in free solution (t1/2 of the order of minutes) persist for hours under the conditions of gel electrophoresis. We have investigated the influence of polyacrylamide gels on the pseudo first-order dissociation kinetics of complexes containing the E.coli cyclic AMP receptor protein (CAP) and lactose promoter DNA. Within the gel matrix, kdiss decreased with increasing [polyacrylamide] and the order of the reaction was changed. In free solution, kdiss was proportional to [DNA]2, while in 5% gels, kdiss was proportional to [DNA]0.3. In gels of [polyacrylamide] > or = 10%, kdiss was nearly independent of [DNA] until fragment concentrations exceeded 0.1 microM. Even in the absence of competing DNA, kdiss(gel) < kdiss(solution). These results suggest that the lifetime of CAP-DNA complexes in free solution is limited by their encounter frequency with molecules of DNA or with protein-DNA complexes; some or all of the stabilization observed in gels may be due to a reduction in this frequency.     

Manual 768 or 384 well microplate gel 'dry' electrophoresis for PCR checking and SNP genotyping

Electrophoresis continues to be a mainstay in molecular genetic laboratories for checking, sizing and separating both PCR products, nucleic acids derived from in vivo or in vitro sources and nucleic acid-protein complexes. Many genomic and genetic applications demand high throughput, such as the checking of amplification products from many loci, from many clones, from many cell lines or from many individuals at once. These applications include microarray resource development and expression analysis, genome mapping, library and DNA bank screening, mutagenesis experiments and single nucleotide polymorphism (SNP) genotyping. PCR hardware compatible with industry standard 96 and 384 well microplates is commonplace. We have previously described a simple system for submerged horizontal 96 and 192 well polyacrylamide or agarose microplate array diagonal gel electrophoresis (MADGE) which is microplate compatible and suitable for PCR checking, SNP typing (restriction fragment length polymorphism or amplification refractory mutation system), microsatellite sizing and identification of unknown mutations. By substantial redesign of format and operations, we have derived an efficient 'dry' gel system that enables direct 96 pin manual transfer from PCR or other reactions in microplates, into 768 or 384 well gels. Combined with direct electrode contact in clamshell electrophoresis boxes which plug directly to contacts in a powered stacking frame and using 5-10 min electrophoresis times, it would be possible (given a sufficient supply of PCRs for examination) for 1 million gel tracks to be run per day for a minimal hardware investment and at minimal reagent costs. Applications of this system for PCR checking and SNP genotyping are illustrated.     

A method to identify individual proteins in four different two-dimensional gel electrophoresis systems: application to Escherichia coli ribosomal proteins.

Agarose gel electrophoresis offers a versatile means to fractionate nucleic acids varying in size over considerably different molecular weight ranges. Surface cohesion properties of agarose gels and sample loading problems have hampered the use of such gels in largediameter, preparative-scale tube gel electrophoresis. We report here a procedure that makes routine and reproducible the construction, sample loading, and running of preparative agarose electrophoretic gels. Data are presented on the fractionation of yeast nucleic acids.     

A method for horizontal polyacrylamide slab gel electrophoresis

We present a simplified method of preparation of polyacrylamide gels which is totally analogous to the procedure now widely used to pour and run horizontal agarose gels. The acrylamide is poured into an open air gel mold consisting of a glass plate with a masking tape border and a comb. It is subsequently run in a submarine horizontal electrophoresis apparatus. The electrophoretic mobility and resolution of DNA fragments obtained in such gels are identical to results obtained with gels poured and run in the vertical configuration. Numerous advantages of horizontal polyacrylamide gel electrophoresis are discussed.     

一步法电泳分析肌联蛋白亚型和肌球蛋白重链

目的为研究超大分子量肌小节蛋白肌联蛋白(titin)的生理病理功能,在一次电泳过程中同时分离titin各亚型和中分子量肌小节蛋白肌球蛋白重链(myosin heavy chain,MHC)。方法使用16cm×18cm垂直电泳系统,在电泳板下1/3灌注10g/L SDS-PAGE胶,上2/3灌注60g/L SDS-琼脂糖(SDS-VAGE)胶。低温8℃下持续电泳5h,在电泳板上层以SDS-VAGE胶电泳分离titin亚型,下层以SDS-PAGE胶电泳分离MHC。电泳后VAGE胶使用银染法标记titin各亚型,PAGE胶使用考马斯亮蓝染色法标记MHC。结果 titin各亚型得到有效的分离,目标蛋白条带显示清晰,与其分子量大小一一对应,分离效果明确。结论一步法垂直电泳系统可应用于超大分子量蛋白的电泳,同时可分离多个分子量差距大的蛋白,提高蛋白电泳实验效率。     

Quantitative aspects of mercurial-agarose gel electrophoresis

Single-stranded nucleic acids are capable of extensive intramolecular base pairing as well as intermolecular aggregation. Consequently, electrophoretic studies of single-stranded nucleic acids are most effective when conducted under denaturing conditions. A number of techniques are available for nucleic acid denaturing gel electrophoresis (1–3). In this paper we describe certain quantitative features of one of these techniques, mercurial-agarose gel electrophoresis (4–7). Specifically, we address the questions of resolution and base composition dependence and we introduce a new mercurial for agarose gel electrophoresis, p-chloromercuriphenyl-sulfonic acid.In a previous publication we demonstrated that methylmercury was an effective denaturant in an agarose gel (4). The mechanism of denaturation is presumably the disruption of hydrogen bonding by the reversible binding of methylmercury to uridine and guanosine imino nitrogens. At saturating mercurial concentrations accurate molecular weights can be determined, free of conformation effects. The presence of methylmercury has no observable effect on the mechanical properties of the gel. Hence the denaturing power of the gel can be readily varied. The strength and rigidity of agarose gels make them considerably easier to handle than acrylamide gels, and the large pore size ensures a system compatible with high molecular weight RNA.     

Binding and purification of plasmid DNA using multi-layered carbon nanotubes

We propose a new method for the separation of nucleic acids using multi-layered carbon nanotubes (CNTs) as an adsorbent. According to agarose gel electrophoresis, oxidized water-stable CNTs adsorb certain forms of nucleic acids, such as high molecular weight RNA, chromosomal DNA, linear and denatured forms of plasmid DNA. However, CNTs do not adsorb supercoiled form of plasmid DNA. Nucleic acids bound to CNTs can be readily removed by centrifugation whereas supercoiled plasmid DNA remains in solution. Upon the addition of divalent metal ions supercoiled plasmid DNA forms relatively stable complexes with CNTs due to chelation. Thus, new details about association of nucleic acids with CNTs were revealed and stoichiometry of the complexes was estimated. Our results can be used for fine purification of supercoiled plasmid DNA for gene therapy applications as well as manipulation of nucleic acids for biosensor design.     

Analysis of the electrophoretic properties of double-stranded DNA and RNA in agarose gels at a finite voltage gradient

The electrophoretic mobilities of double-stranded (ds) DNAs and ds RNAs of various lenths, L, were measured in gels of 0.4–1.8% (w/v) agarose at a voltage gradient of 1.0 V/cm. Differences in the electrophoresis of ds DNA and ds RNA are presented and discussed. A general expression is derived that describes the electrophoretic mobility, M, of either type of ds nucleic acid as a function of the gel concentration and the nucleic acid length: M = M′₁(L/L₀)^?x ? M₂, where M′₁ and L₀ are constants, and x and M₂ depend on the agarose gel concentration. The results obtained by fitting our data with this equation are consistent with the mobilities of nucleic acids in a wide range of gel concentrations, including free electrophoresis in solution and electrophoresis in gles of high agarose concentration in which nuleic acids are expected to reptate through the gel matrix. Finally, various methods of plotting agarose gel electrophoresis data are discussed.     

Transient electric birefringence of agarose gels. II. Reversing electric fields and comparison with other polymer gels

The transient electric birefringence of low electroendosmosis (LE) agarose gels oriented by pulsed unidirectional electric fields was described in detail in Part I [J. Stellwagen and N. C. Stellwagen (1994), Biopolymers, Vol. 34, p. 187]. Here, the birefringence of LE agarose gels in rapidly reversing electric fields, similar in amplitude and duration to those used for field inversion gel electrophoresis, is reported. Symmetric reversing electric fields cause the sign of the birefringence of LE agarose gels, and hence the direction of orientation of the agarose fibers, to Oscillate in phase with the applied electric field. Because of long-lasting memory effects, the alternating sign of the birefringence appears to be due to metastable changes in gel structure induced by the electric field. If the reversing field pulses are equal in amplitude but different in duration, the orientation behavior depends critically on the applied voltage. If E < 7 V/cm, the amplitude of the birefringence gradually decreases with increasing pulse number and becomes unmeasurably small. However, if E > 7 V/cm, the amplitude of the birefringence increase more than 10-fold after ～ 20 pulses have been applied to the gel, suggesting that a cooperative change in gel structure has occurred. Because there is no concomitant change birefringence must be due to an increase in the number of agarose fibers and /or fiber bundles orienting in the lectric field, which in turn indicates a cooperatice breakdown of the noncovalent “junction zones” that corss-link the fibers in to the fgel matrix. The sign of the birefringence of LE agarose gels is always positive after extensive junction zone breakdown, indicating that the agarose fibers and fiber bundles preferentially orient parallel to the lectric field when they are freed from the constraints of the gel matrix. Three other gel-forming polymers, high electroendosmosis (HEEO) agarose (a more highly changed agarose), β-carrageenan (a stereoisomer of agarose), and polyacrylamide (a chemically corss-linked polymer) were alos studied in unidirectional and rapidly reversing electric fields. The birefringence of HEEO agarose backbone chain. The β-carrageenan gels exhibit variable orientation behavior in reversing electric fields, suggesting that its internal gel structure is not as tightly interconnected as that of agaroise gels. Both HEEO agarose and β-carrageenan gels exhibit a large increase in the amplitude of the birefringence with increasing pulse number when asymmetric reversing pulses > 7 V/cm are applied to the gels, suggesting that junction zone breakdown in a common feature of polysaccharide gels. Chemically cross-linked polyacrylamide gels exhibit very small birefringence signals, indicating that very little orientation occurs in pulsed lectric fields. The sign of the birefringence is independent of the polarity of the lectric field, as expected from the Kerr law, and normal orientation behavior is observed in reversing electric fields. Hence, the anomalous change in sign of the birefringence observed for agarose gels in reversing electric fields must be due to the metastable junction zones in the agarose gel matrix, which allow gel fiber rearrangements to occur. © 1994 John Wiley & Sons, Inc.     

Electrophoretic mobility shift assay (EMSA) for detecting protein-nucleic acid interactions

The gel electrophoresis mobility shift assay (EMSA) is used to detect protein complexes with nucleic acids. It is the core technology underlying a wide range of qualitative and quantitative analyses for the characterization of interacting systems. In the classical assay, solutions of protein and nucleic acid are combined and the resulting mixtures are subjected to electrophoresis under native conditions through polyacrylamide or agarose gel. After electrophoresis, the distribution of species containing nucleic acid is determined, usually by autoradiography of 32P-labeled nucleic acid. In general, protein-nucleic acid complexes migrate more slowly than the corresponding free nucleic acid. In this protocol, we identify the most important factors that determine the stabilities and electrophoretic mobilities of complexes under assay conditions. A representative protocol is provided and commonly used variants are discussed. Expected outcomes are briefly described. References to extensions of the method and a troubleshooting guide are provided.     

Rapid re-amplification of PCR products purified in low melting point agarose gels

A rapid, simple method is described for performing sequential amplifications of purified products produced by the PCR. After the initial amplification, an aliquot of the reaction is run on a low melting point agarose gel. A Pasteur pipet is used to punch out a gel plug from the amplified band. The DNA in this plug is then used directly as the template for a second round of amplification. Relatively large amounts of agarose can be tolerated without noticeable effects on amplification. Use of a composite gel made from agarose and linear polyacrylamide increases the ease and utility of this technique. These gels are simple to cast, easier to handle and permit several replicate plugs to be obtained from a single band. This method is well suited to experiments which use "nested" primers to increase the sensitivity and specificity of amplification or any method in which PCR amplification follows DNA purification by electrophoresis in LMP agarose gels.     

Electrophoretic mobility of high-molecular-weight, double-stranded DNA on agarose gels.

A new theoretical model for the migration of high-molecular-weight, double-stranded DNA on agarose gels is presented. This leads to the prediction that under certain conditions of electrophoresis, a linear relationship will exist between the molecular weight of a DNA molecule, raised to the (-2/3) power, and its electrophoretic mobility. Agarose gel electrophoresis of the fragments of bacteriophage lambda DNA produced by several restriction endonucleases confirms this relationship, and establishes some of the limits on its linearity. For this work, a polyacrylamide slab gel apparatus was modified for use with agarose gels. This apparatus has several advantages over others commercially available for agarose gel electrophoresis, including the abilities to run a larger number of samples at one time, to use lower-concentration gels, and to maintain better temperature stability across the width of the gel. The validation of the relationship developed here between molecular weight and electrophoretic mobility should make this a useful method for determining the molecular weights of DNA fragments.