An angle-variable three-dimensional pulsed field gel electrophoresis system

A three-dimensional pulsed field electrophoretic method based on the simultaneous application of fixed and cyclically alternating polarity fields at a right angle is described. Requiring only minimal electronic hardware it provides highly homogeneous field conditions over a large gel area and the versatility to vary the pulse vector angle. The electrophoretic parameters critical to achieve fast high resolution separation over a wide range of molecular sizes have been optimized and applied to megabase-size chromosomal DNA molecules. The empirical relationships between pulse time, field strength conditions, and resolution limits derived allow selection of coordinated experimental conditions for the separation of specific DNA size ranges.     

Separation of the DNA molecules beyond conventional size limits by gel electrophoresis with sodium dodecyl sulfate.

Electrophoretic mobility of DNA through polyacrylamide as well as agarose gels is greatly increased by sodium dodecyl sulfate (SDS). DNA molecules well beyond the conventionally separable size limits are separated readily and rapidly by gel electrophoresis with SDS in a conventional static electric field. Furthermore in optimal concentration gels DNA molecules of similar molecular sizes are separated better from one another in the presence of SDS than without it. Evidence is presented that SDS may act at least in part by altering conformation of DNA. This simple and readily available means for high resolution separation of hitherto impossible sizes of DNA molecules in polyacrylamide and agarose gels in an ordinary static electric field should find general use in molecular genetic analyses. Structural analyses of DNA-protein complexes are also facilitated by virtue of the simultaneous separation of the DNA and protein components on the same gel lane.     

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.     

Microfabricated polymer chip for capillary gel electrophoresis

A polymer (PDMS: poly(dimethylsiloxane)) microchip for capillary gel electrophoresis that can separate different sizes of DNA molecules in a small experimental scale is presented. This microchip can be easily produced by a simple PDMS molding method against a microfabricated master without the use of elaborate bonding processes. This PDMS microchip could be used as a single use device unlike conventional microchips made of glass, quartz or silicon. The capillary channel on the chip was partially filled with agarose gel that can enhance separation resolution of different sizes of DNA molecules and can shorten the channel length required for the separation of the sample compared to capillary electrophoresis in free-flow or polymer solution format. We discuss the optimal conditions for the gel preparation that could be used in the microchannel. DNA molecules were successfully driven by an electric field and separated to form bands in the range of 100 bp to 1 kbp in a 2.0% agarose-filled microchannel with 8 mm of effective separation length.     

Pulsed field gradient electrophoresis of DNA digested in agarose allows the sizing of the large duplication unit of a surface antigen gene in trypanosomes

Intact chromosome-sized DNA molecules from eukaryotes may be prepared by performing lysis and enzymic deproteinization on cells embedded in agarose [Schwartz and Cantor, Cell 37 (1984), 67-75]. Here we show that DNA prepared by this method may be cut with restriction enzymes, or modified with site-specific methylases and cut by DpnI. As the DNA remains incorporated in the gel matrix, shear degradation of large fragments is avoided. The fragments can then be sized by conventional or pulsed field gradient gel electrophoresis. Phage lambda genomic oligomers are used as size markers, allowing the estimation of fragment sizes up to about 1200 kb. We apply these techniques to show that activation of the telomeric gene encoding variant surface antigen 1.3 in Trypanosoma brucei strain 427, involves the duplication of a DNA segment that starts between 29 and 42 kb upstream of the gene and to assign a chromosomal fragment into which the duplicated 1.3 gene may have transposed.     

Computer-controlled discontinuous rotating gel electrophoresis for separation of very large DNA molecules

The newly designed equipment for alternating field gel electrophoresis which permits the separation of very large DNA molecules and the simultaneous analysis of up to 35 samples is described. The field alternation is effected by intermittently rotating the submerged agarose gel by optitional angles. The time intervals between changes of position are controlled by a computer program driving a simple switching device which was designed to suit any technique using periodic switching or inversion of the electrical field. Because the electrophoresis unit provides an absolutely homogeneous electrical field, no distortion of migration lanes occurs and the resolution is very good. Moreover, by using a switching time interval gradient an almost perfect linear relationship between migration distances and molecule sizes in the range of about 100-1250 kilobase pairs is observed. In two-dimensional separations, different switching time programs for the first and second dimension allow maximum resolution of selected size ranges. Field inversion gel electrophoresis is possible as well. The performance of the method is demonstrated by comparing the chromosome sizes of different yeast strains.     

Structural aberrations in T-even bacteriophage. VI. Molecular weight of DNA from giant heads

Cummings et al. (1973) reported that whenl-canavanine was chased from a T-even. bacteriophage-infected culture with its analog,l-arginine, a new type of aberrant particle was formed. These particles, which were termed “lollipops”, had giant heads as long as 44 normal head lengths, and were filled with DNA. We have now separated these particles into different size classes ranging from about three to 13 normal head lengths and measured the molecular weight of their DNA. The DNA released from intact phage particles by neutral or alkaline detergent lysis was characterized using a recently described biophysical technique which determines DNA molecular weight from solution viscoelasticity. The maximum DNA size correlated roughly with phage head length, indicating that these giant heads were often filled with single, long DNA molecules rather than with several normal-sized molecules. Many of the heads, however, must have contained several molecules, since a large amount of DNA of less than maximum size was present. In alkali the native molecules separated into single strands of approximately the same length as that of the native molecules.     

Enrichment and visualization of small replication units from cultured mammalian cells

DNA from cultured Chinese hamster cells has been fractionated to yield a population of DNA enriched for replicating molecules. Molecules containing replication structures were analyzed by electron microscopy, and replicon size was estimated. The enrichment procedure takes advantage of single-stranded regions characteristic of replicating molecules, and the greater affinity of mercuric ion for single-stranded rather than native DNA. After interaction with low concentrations of HgCl2, DNA with bound mercury is separated from the bulk of the DNA by virtue of its increased buoyant density in an isopycnic Cs2SO4 gradient. When DNA from cells labeled with [3H]thymidine for 45 s is interacted with HgCl2 and banded in Cs2SO4, the DNA with the highest specific activity is found in a dense region of the gradient. The high specific activity DNA behaves kinetically like nascent DNA since the radioactivity can be chased into main band if the cells are incubated for a further 2 h in excess unlabeled thymidine. Electron microscope analysis of the DNA in the enriched fraction confirmed that it contains a substantial fraction of molecules with replication structures. The level of enrichment is about 25-fold compared to unfractionated DNA or DNA taken from the main band of the Hg++/Cs2SO4 gradient. Of the replicating molecules visualized, 85% possessed a single replication structure. All molecules with multiple replication forms contained replicon sizes less than 5 micron, ranging from 0.2 to 4.5 micron. Replicon size was determined by measuring the distance from the center of one replication structure to the center of the adjacent replication structure on the same molecule. The replicons observed in this study are far smaller than can be detected by DNA fiber autoradiography and are in the same size range as the very small replication units reported in embryonic systems.     

Restriction mapping of recombinant lambda DNA molecules using pulsed field gel electrophoresis

We have integrated pulsed field gel electrophoresis with the partial digestion strategy of Smith and Birnstiel (1976, Nucleic Acids Res. 3,2387-2398) to generate a rapid and accurate method of restriction endonuclease mapping recombinant lambda DNA molecules. Use of pulsed field gels dramatically improves the accuracy of size determination and resolution of DNA restriction fragments relative to standard agarose gels. Briefly, DNA is partially digested with restriction enzymes to varying extents and then hybridized with a radiolabeled oligonucleotide which anneals specifically to one of the lambda cohesive (cos) ends, effectively end labeling only those digestion products containing that cos end. In this study, we have used an oligonucleotide hybridizing to the right cos end. DNA is then fractionated by pulsed field gel electrophoresis, the gel dried down, and cos end containing fragments visualized by autoradiography. Fragment sizes indicate the distances from the labeled cos end to each restriction site for the particular restriction enzyme employed. This procedure requires only minimal quantities of DNA and is applicable to all vectors utilizing lambda cos ends.     

Electrophoretic analysis of Histoplasma capsulatum chromosomal DNA.

Seven chromosome-sized DNA molecules in the Downs strain of Histoplasma capsulatum were resolved by using chromosome-specific DNA probes in blot hybridizations of contour-clamped homogeneous electric field (CHEF) and field-inversion gel electrophoresis (FIGE) agarose gels. The sizes of the chromosomal DNA bands extended from that of the largest Saccharomyces cerevisiae chromosome to beyond that of the Schizosaccharomyces pombe chromosomes. Under our experimental conditions, the order of the five largest DNA bands was inverted in the FIGE gel relative to the CHEF gel, demonstrating a characteristic of FIGE whereby large DNA molecules may have greater rather than lesser mobility with increasing size. Comparison of the Downs strain with other H. capsulatum strains by CHEF and FIGE analysis revealed considerable variability in band mobility. The resolution of seven chromosome-sized DNA molecules in the Downs strain provides a minimum estimate of the chromosome number.     

Rapid separation of DNA molecules by agarose gel electrophoresis: use of a new agarose matrix and a survey of running buffer effects.

This report describes the use of a new type of agarose (FastLane agarose) for faster separation of DNA by agarose gel electrophoresis. DNA molecules separated in this agarose exhibited electrophoretic mobilities up to 30% higher than similar separations in standard analytical grade agarose. DNA molecules of all sizes examined showed higher mobilities in FastLane agarose. The mobility increase was predominantly due to the low electroendosmosis of FastLane agarose and was most pronounced in pulsed field gel electrophoresis separations. The magnitude of mobility increase varied depending on the conditions used for electrophoresis.     

Improved separation of chromosome-sized DNA from Trypanosoma brucei, stock 427-60.

Separation of chromosome-sized DNA from the parasitic protozoan Trypanosoma brucei had previously resulted in the fractionation of DNA molecules that ranged in size from 50 kb up to roughly 1.5 Mb. The number of larger chromosomes and their size, accounting for 80% of the DNA of T. brucei remained unclear. We have now size separated these larger DNA molecules by pulsed field gel electrophoresis (PFG) and resolve a total of 20 bands, accounting for roughly 120 chromosomes, ranging in size from 50 kb up to the size of the largest, 5.7 Mb chromosome of Schizosaccharomyces pombe. Three different VSG gene expression sites were located to chromosomes of 430 kb, 1.5 Mb and 3 Mb, respectively. We have not been able to identify additional, previously cryptic DNA rearrangements, that could explain the activation or inactivation of the expression sites.     

Pulsed field gel electrophoresis techniques for separating 1- to 50-kilobase DNA fragments

Conventional agarose gel electrophoresis separates DNA using a static electric field. The maximum size limit for separation of DNA by this method is about 20 kilobase pairs (kb). A number of new electrophoretic techniques which employ periodic reorientation of electric fields permit separation of DNA well beyond this size limit. We sought to determine whether the use of very fast (millisecond) field switching could improve separation of DNA in the size range of 1 to 50 kb. Additionally, we have compared the resolution obtained with each of the different field switching regimens for DNA in this size range. Switching intervals of from 0.2 to 900 ms were used with unidirectional pulsing of a single electric field, with pulsed field gels, and with field inversion gel electrophoresis. Plotting the mobility of DNA as a function of size demonstrates that under the conditions used, each of these techniques offers comparable resolution. We also have examined the separation obtained when field inversion gels are run with forward and reverse fields of equal voltage and different durations, versus using fields of equal duration and different voltages. Field inversion which uses forward and reverse fields of different voltages yields resolution which is superior to the other methods examined.     

Characterization of polymers of adenosine diphosphate ribose generated in vitro and in vivo

Methods have been developed and applied to determine the size and branching frequency of polymers of ADP-ribose synthesized in nucleotide-permeable cultured mouse cells and in intact cultured cells. Polymers were purified by affinity chromatography with a boronate resin and were fractionated according to size molecular sieve high-performance liquid chromatography. Fractions were enzymatically digested to nucleotides, which were separated by strong anion exchange high-performance liquid chromatography. From these data, average polymer size and branching frequency were calculated. A wide range of polymer sizes was observed. Polymers as large as 190 residues with at least five points of branching per molecule were generated in vitro. Polymers of up to 67 residues containing up to two points of branching per molecule were isolated from intact cells following treatment with the DNA alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine. Cells treated with hyperthermia prior to DNA damage contained polymers of an average maximum size of 244 residues containing up to six points of branching per molecule. The detection of large polymers of ADP-ribose in intact cells suggests that alterations in chromatin organization effected by poly(ADP-ribosylation) may extend beyond the covalently modified proteins and very likely involve noncovalent interactions of poly(ADP-ribose) with other components of chromatin.     

Unidirectional pulsed-field electrophoresis of single- and double-stranded DNA in agarose gels: analytical expressions relating mobility and molecular length and their application in the measurement of strand breaks

Unidirectional pulsed-field electrophoresis improves the separation of single-stranded DNA molecules longer than 20 kilobases (kb) in alkaline agarose gels compared to static-field electrophoresis. The greatest improvement in separation is for molecules longer than 100 kb. The improved resolution of long molecules with unidirectional pulsed-field electrophoresis makes possible the measurement of lower frequencies of single-strand breaks. The analytical function that relates the length and mobility of single-stranded DNA electrophoresed with a static field also applies to unidirectional pulsed field separations. Thus, the computer programs used to measure single-strand breaks are applicable to both undirectional pulsed- and static-field separations. Unidirectional pulsed-field electrophoresis also improves the separation of double-stranded DNA in neutral agarose gels. The function relating molecular length and mobility for double-stranded DNA separated by unidirectional pulsed-field electrophoresis is a superset of the function for single-stranded DNA. The coefficients of this function can be determined by iterative procedures.     

Size-dependent, chromatographic separation of double-stranded DNA which is not based on gel permeation mode

A new procedure for size-dependent fractionation of DNA was investigated. DNA fragments ranging from 10 to 40 kbp were separated by using columns for high-performance gel permeation chromatography. However, the order of elution was opposite to that which would be expected for gel permeation chromatography, i.e., smaller fragments were eluted faster than larger fragments, though separation based on normal gel permeation chromatography was observed when smaller DNA fragments (less than 5 kbp) were applied. The size range of DNA which can be resolved by this new procedure was found to depend on both particle size and flow rate; the use of a column packed with smaller particles or the application of a faster flow rate enabled us to resolve smaller DNA fragments, but the pore size or chemical nature of the column packing had scarcely any effect on the resolution. This mode of separation was attained by using both silica and polymer packings. The results suggest that the separation is based on a hydrodynamic phenomenon.     

Nonlinear electrophoresis and focusing of macromolecules

Effects of nonlinear dependence drift velocity of (double-stranded) DNA vs. electric field strength were investigated. In comparatively weak fields, the molecular drift velocity is proportional to the external electric field, while in strong fields there is additional nonlinear component. This effect offers possibilities to manipulate the total drift velocity at will-the macromolecules of different size can be made to move in opposite directions in pulsed field gel electrophoresis.A new approach for focusing DNA molecules based on nonlinear electrophoresis and geometric trapping in electric fields is proposed. The focusing is carried out in an alternating nonuniform electric field, created by using a wedge gel with hyperbolic boundaries. It is shown that the fractions separated in such wedge retain their rectilinear shape.Gel electrophoresis experiments supported the possibility of a pronounced nonlinear focusing of DNA molecules. This nonlinear separation technique presents encouraging prospects for micromanipulating systems and also for preparative isolation of long DNA fragments and development of new separation methods for bacterial fingerprinting.     

Circular and linear DNA molecules in the Entamoeba histolytica complex molecular karyotype

Entamoeba histolytica genome was analysed by pulsed field gel electrophoresis under conditions to separate linear chromosomes in the 170–1400 kb range. We identified linear DNA molecules of 227, 366, 631, 850, 1112 and 1361 kb (mean sizes obtained by three different methods) and we estimated their reorientation times and migration velocities at various experimental conditions. DNA shift mobility assays, using ethidium bromide, suggested that bands migrating at 227 and 631 kb contain linear and circular DNA, whereas a band at 436 kb has only circular DNA. We obtained a regression equation relating sizes of supercoiled DNA molecules with their migration velocities during a pulse at constant electric field and temperature. We also developed a computer program (EHPATTERNS) that predicts the migration per pulse and the resolution order of circular and linear E. histolytica DNA at different pulse times and constant driving and frictional forces. The simulation showed that linear DNA molecules frequently co-migrate with circular molecules, but circular molecules change when the pulse time varies. This molecular mixture generates broad bands and difficulties in the interpretation of the molecular karyotype of E. histolytica. Received: 19 January 1999 / Revised version: 3 November 1999 / Accepted: 22 November 1999     

Identification of small nuclear DNA molecules of the cuban sugarcane cultivar Ja60-5 via pulsed field gel electrophoresis

We present evidence of the existence of at least 7 small nuclear DNA molecules in the Ja60-5 sugarcane cultivar genome. These small molecules were separated by means of transversal alternating field electrophoresis (TAFE); their sizes ranged from about 230–3000 kbp, and they hybridized with telomeric, subcentromeric, and various nuclear DNA probes. Here, we also report the use and the modifications of DNA from microorganisms, to immobilize nuclear DNA from sugarcane suitable for analysis via pulsed field gel electrophoresis. The protocol is simple, inexpensive, and easy to perform.     

Accurate evaluation of the sizes of DNA fragments (from 30 to 4700 kb) in pulse field gel electrophoresis.

Construction of long-range genomic maps by pulse field gel electrophoresis requires optimum resolution of large DNA fragments. Using the transverse-alternating field electrophoresis system, we describe a method to accurately evaluate the sizes of fragments generated by rare-cutter digestions within the 30-4700-kb range. A protocol generating large (greater than 1000 kb) molecules by partial digestion is also reported.