Pulsed field gel electrophoresis: Theory,instruments and application

Pulsed field gel electrophoresis (PFGE) is a technique for the fractionation of high-molecular-weight DNA ranging from 10 kb to 10 Mb by electrophoresis in agarose gel with an electric field that alternates (pulsates) in two directions. This technology plays a key role in modern genomics, as it allows manipulations with DNA of whole chromosomes or their large fragments. In this review, we discuss (1) the theory behind PFGE; (2) different instruments based on the principle of pulsed field, as well as their advantages and limitations; (3) factors affecting the DNA mobility in PFGE gel; and (4) practical applications of the technique.     

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

Pulsed field gel electrophoresis (PFGE) techniques have been developed to overcome the limitations of conventional electrophoresis and to increase the separation to DNA chromosomes of few megabase pairs in size. Despite of the large success of these techniques, the various separation protocols employed for PFGE experiments have been determined empirically. However, a deep understanding of the molecular mechanisms of motion responsible for DNA separation becomes necessary for the rational optimization of these techniques. This paper shows the first clear observations of individual molecules of DNA during the reorientation process in 90 degrees PFGE and 120 degrees PFGE. Real-time visualization of the DNA dynamics during PFGE was possible with the use of an epi-illumination fluorescence microscope specifically equipped to run these experiments and by staining the DNA with YOYO-1 (1,1'-(4,4,7,7-tetramethyl-4,7-diazaundecamethylene)-bis-4-[3-meth yl -2,3-dihydro-(benzo-1,3-oxazole)-2-methyl-idene]-quinolinium tetraiodide). This dye forms a very stable, highly fluorescent complex with double-stranded DNA and dramatically improves the quality of the DNA images. The results of computer simulations used to reproduce the molecular mechanisms of motion as well as the DNA separation features are also discussed.     

Electrophoretic mobility of DNA in gels. I. New biased reptation theory including fluctuations

In weak electric fields, the motion of DNA molecules undergoing gel electrophoresis may be described by biased reptation. We argue that the degree of molecular orientation induced by the field is determined by a competition between longitudinal fluctuations and drift of the molecule along the tube. A self-consistent calculation shows that the end-to-end vector of long molecules varies with the square root of the field strength, and not linearly as previously supposed. This leads to a number of new predictions about the field dependence of the molecular mobility and the size limit of resolution. We present the results of computer simulations that support the predictions of the theory of biased reptation including fluctuations. Finally, we discuss the correspondence with experimental data and the implications of our findings for the optimization of DNA electrophoresis. © 1994 John Wiley & Sons, Inc.     

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)     

Imaging of kinked configurations of DNA molecules undergoing orthogonal field alternating gel electrophoresis by fluorescence microscopy

The dynamics of individual DNA molecules undergoing orthogonal field alternating gel electrophoresis (OFAGE) have been studied by use of T2 DNA molecules labeled with a dye and visualized with a fluorescence microscope. The mechanism of reorientation used by a molecule to align itself in the direction of the new orthogonal field depends on the degree of extension of the chain immediately before the application of this field. The formation of kinks is promoted when time is allowed between the application of the two orthogonal fields so that the molecule attains a partially relaxed configuration. In this case, the chain appears bunched up in domains moving along the contour of the molecule. These regions are found to be the locations where the kinks are formed upon application of the second field perpendicular to the chain. The formation of kinks provides a significant retardation of the reorientation of the molecules, relative to molecules that do not form kinks, and appears to play an important role in the fractionation attained with OFAGE. A classification of various reorientation mechanisms observed in molecules that form kinks is presented.     

Trapping and breaking of in vivo nicked DNA during pulsed field gel electrophoresis

Pulsed field gel electrophoresis (PFGE) offers a high-resolution approach to quantify chromosomal fragmentation in bacteria, measured as percentage of chromosomal DNA entering the gel. The degree of separation in pulsed field gel (PFG) depends on the size of DNA as well as various conditions of electrophoresis such as electric field strength, time of electrophoresis, switch time, and buffer composition. Here we describe a new parameter, the structural integrity of the sample DNA itself, that influences its migration through PFGs. We show that subchromosomal fragments containing both spontaneous and DNA damage-induced nicks are prone to breakage during PFGE. Such breakage at single-strand interruptions results in artifactual decrease in molecular weight of linear DNA making accurate determination of the number of double-strand breaks difficult. Although breakage of nicked subchromosomal fragments is field strength independent, some high-molecular-weight subchromosomal fragments are also trapped within wells under the standard PFGE conditions. This trapping can be minimized by lowering the field strength and increasing the time of electrophoresis. We discuss how breakage of nicked DNA may be mechanistically linked to trapping. Our results suggest how to optimize conditions for PFGE when quantifying chromosomal fragmentation induced by DNA damage.     

Modeling the free solution and gel electrophoresis of biopolymers: the bead array-effective medium model

Free solution and gel electrophoresis is an extremely useful tool in the separation of biopolymers. The complex nature of biopolymers, coupled with the usefulness of electrophoretic methods, has stimulated the development of theoretical modeling over the last 30 years. In this work, these developments are first reviewed with emphasis on Boundary Element and bead methodologies that enable the investigator to design realistic models of biopolymers. In the present work, the bead methodology is generalized to include the presence of a gel through the Effective Medium model. The biopolymer is represented as a bead array. A peptide, for example, made up of N amino acids is modeled as 2N beads. Duplex DNA is modeled as a discrete wormlike chain consisting of touching beads. The technical details of the method are placed in three Appendices. To illustrate the accuracy and effectiveness of the approach, two applications are considered. Model studies on both the free solution mobility of 73 peptides ranging in size from 2 to 42 amino acids, and the mobility of short duplex DNA in dilute agarose gels are discussed.     

Theory of gel electrophoresis of DNA

A theory of the electrophoresis of DNA through gels with large interfiber spacing, such as dilute agarose, is presented. We assume that the DNA molecule moves along its axis through a “tube” in a neutral gel under the influence of the electric field. The tube is random except for possible bias due to the effects of the field. When the field is small, we easily recover the inverse-length dependence of the mobility found previously by de Gennes and by Doi and Edwards. At higher fields, a new effect appears; the tube becomes oriented because the field biases the direction of the leading end of the chain as it moves to form an extension of the tube. This leads to an increase of the mobility with increasing field by adding a field-dependent but length-independent term to the mobility expression. In agreement with experiment, we find that the field effect can be important at fields as low as 1 V/cm and that the effect can seriously decrease the sensitivity of the mobility to chain length. We also examine the fluctuation of the migration distance, the degree of orientation induced by the field, and the transient effects occurring when the feld direction is rotated by a right angle.     

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.     

脉冲电泳不同参数对介导GFP基因转化玉米种胚效果的研究

利用脉冲电泳介导绿色荧光蛋白(GFP)基因导入玉米种胚;以GFP基因在种胚中瞬时表达作为外源基因导人种胚细胞的标记,分析了外源．DNA浓度、电泳时间、电压、电流转换时间等脉冲电泳转化参数对种胚发芽率和外源基因导入率的影响。结果表明：脉冲电泳时间对种胚发芽率和外源GFP基因导入率影响最大;通过脉冲电泳可将外源基因导入胚芽细胞,其GFP基因导人种子的频率与各电泳参数均呈二次曲线关系,300μg／ml外源DNA浓度、120min电泳时间、5V电压、2s电流转换时间可作为脉冲电泳介导玉米种胚转化较适宜的参数。     

Rapid pulsed field separation of DNA molecules up to 250 kb.

Pulsed field gel electrophoresis (PFGE) is capable of resolving a wide size range of DNA molecules which would all co-migrate in conventional agarose gels. We describe pulsed field gel conditions which permit DNA fragments of up to 250 kilobases (kb) to be separated in only 3.5 h. The separations, which employ commercially available gel boxes, are achieved using conditions which deviate significantly from traditional pulsed field conditions. PFGE separations have been thought to require reorientation angles greater than 90 degrees to be effective. However, reorientation angles of 90 degrees and even less will resolve DNA fragments a few hundred kb and smaller approximately 5 x faster than with standard pulsed field conditions. The mobility of DNA fragments separated with 90 degrees reorientation angles is switch time-dependent, as is seen for DNA run with the commonly used reorientation angle of 120 degrees. With DNA fragments of several hundred kb and smaller, higher field strengths may be used, resulting in still greater increases in separation speed. The conditions described allow DNA from large insert bacterial clones, such as those using cosmid, Fosmid, P1, bacterial artificial chromosome (BAC), or P1-derived artificial chromosome (PAC) vectors, to be prepared, digested and analyzed on gels within a single working day.     

Circular DNA of 3T6R50 double minute chromosomes

In pulsed field gradient gel electrophoresis (PFGE) the intact deproteinized circular DNA of Mycoplasma (800 kb) and Escherichia coli (4700 kb) remains trapped in the slot. We show here that gamma-irradiation of the DNA in agarose plugs is a convenient method to partially convert these circles into full-length linears, migrating with the expected mobility in PFGE. We have used this method to study the structure of Double Minute chromosomes (DMs) from the methotrexate (MTX)-resistant mouse cell line 3T6R50. Intact deproteinized DM DNA is immobile in these gels, but is converted into a single band of about 2500 kb by either gamma-irradiation, DNaseI in the presence of Mn2+, or restriction enzymes. We conclude that the DM DNA in 3T6R50 cells consists of a homogeneous population of 2500-kb circles.     

Pulsed field gel electrophoresis of chromosomal DNA reveals a clonal population structure to Bacillus thuringiensis that relates in general to crystal protein gene content

Seventy strains of Bacillus thuringiensis representing 21 serovars were allocated to 38 genomic groups using pulsed field gel electrophoresis (PFGE) of restriction enzyme-digested DNA. There was a broad correlation between PFGE type and serotype for serovars darmstadiensis, israelensis, kenyae, kumamotoensis, kurstaki, sotto, thuringiensis, and tolworthi, although some serovars included atypical strains. Serovars canadensis and entomocidus were heterogeneous. Detection of crystal protein genes by polymerase chain reaction indicated an approximate correlation between PFGE type and cry gene complement. For example, cry1 products were amplified from DNA from PFGE type 17 strains of serovar aizawai and from PFGE type 23 strains of serovar tolworthi but not from a PFGE 18 strain of aizawai nor from a PFGE type 24 strain of tolworthi. These data suggest a clonal population structure to B. thuringiensis with some consistency of Cry-plasmid composition within PFGE types.     

Development of large DNA methods for plants: molecular cloning of large segments of Arabidopsis and carrot DNA into yeast.

Procedures for the preparation, analysis and cloning of large DNA molecules from two different plant species are described. Arabidopsis and carrot protoplasts were used for the preparation of large DNA molecules in agarose "plugs" or in solution. Pulsed-field gel electrophoresis (PFGE) analysis of large plant DNA preparations using a contour-clamped homogeneous field (CHEF) apparatus indicated that the size of the DNA was at least 12 Mb. Large DNA preparations were shown to be useful for restriction enzyme analysis of the Arabidopsis genome using both frequent and infrequent cutting enzymes and for the molecular cloning of large segments of DNA into yeast using artificial chromosome (YAC) vectors. PFGE and blot hybridization analysis of Arabidopsis and carrot DNA-containing YACs indicated that both unique and highly repeated DNA sequences were represented in these libraries.     

Scrambling of bands in gel electrophoresis of DNA.

Under certain conditions of agarose gel electrophoresis, larger DNA molecules migrate faster than smaller ones. This anomalous mobility of DNA, which can lead to serious errors in the measurement of DNA fragment lengths, is related to near-zero velocity conformations which can trap DNA chains during electrophoresis. Intermittent electric fields can be used to alter the chain conformations so as to restore the monotonic mobility-size relationship which is necessary for a correct interpretation of the gel. These data are in agreement with the results of a computer simulation based on a theoretical model of electrophoresis.     

脉冲场凝胶电泳技术及其在真菌学研究中的应用

脉冲电泳是用于分离大分子量DNA的一种电泳技术,已广泛用于真菌的核型分析,种群特异性鉴定,基因定位及遗传分析的研究。介绍了脉冲电泳的原理,发展和基本操作程序,并阐述了脉冲电泳技术在真菌分子生物学研究领域的应用。     

A systematic study of field inversion gel electrophoresis.

The mobilities of oligomers of phage lambda DNA and of yeast chromosomes in agarose gels during field inversion gel electrophoresis (FIGE) were measured at different pulse times and electric fields. Also the ratios between forward and backward pulse times and/or field gradients were varied. The problem of 'band inversion' during FIGE, leading to an ambiguity in the mobility of large DNA fragments, was solved by using two dimensional gel electrophoresis with different parameters in the first and second dimension. The results are compared with those obtained with other pulsed electrophoresis systems and with a theoretical model.     

PFGE MAPPER: a tool to aid in the analysis of pulse field gel electrophoresis maps

Pulse field gel electrophoresis mapping is an important techniquefor characterizing large segments of DNA and constructing long-rangerestriction maps. We have developed a tool, PFGE MAPPER, toaid in the construction of pulse field electrophoresis gel maps.This tool helps construct pulse field gel maps from single anddouble digest experiments visualized by hybridization with singlecopy probes. The program is written in Think C and runs on Macintoshcomputers. An intuitive interface allows the user to interactivelymodify fragment sizes or errors, select fragments for analysisand recalculate the maps. Maps can be printed or saved for laterviewing. After constructing and saving several maps in a region,PFGE MAPPER can be used to refine and extend the overall mapby merging individual maps. This tool should be useful for constructinglong-range restriction maps of genomic DNA and yeast artificialchromosomes.     

Measurement of radiation-induced DNA double-strand breaks by pulsed-field gel electrophoresis

We have examined the use of pulsed-field gel electrophoresis (PFGE) to measure DNA double-strand breaks induced in CHO cells by ionizing radiation. The PFGE assay provides a simple method for the measurement of DNA double-strand breaks for doses as low as 3-4 Gy ionizing radiation, and appears applicable for the measurement of damage produced by any agent producing double-strand breaks. The conditions of transverse alternating field electrophoresis determined both the sensitivity of the assay and the ability to resolve DNA fragments with different sizes. For example, with 0.8% agarose and a 1-min pulse time at 250 V for 18 h of electrophoresis, 0.39% of the DNA per gray migrated into the gel, and only molecules less than 1500 kb could be resolved. With 0.56% agarose and a 60-min pulse time at 40 V for 6 days of electrophoresis, 0.55-0.90% of the DNA per gray migrated into the gel, and molecules between 1500 and 7000 kb could be resolved.     

DNA gel electrophoresis: effect of field intensity and agarose concentration on band inversion

We study the effect of electric field intensity and agarose gel concentration on the anomalous electrophoretic mobility recently predicted by the biased reptation model and experimentally observed for linear DNA fragments electrophoresed in continuous electric fields. We show that high fields and low agarose concentrations eliminate the physical mechanism responsible for anomalous DNA mobility and band inversion, in good agreement with theory, thus restoring the monotonic mobility-size relationship necessary for unambiguous interpretation of the results of DNA gel electrophoresis.