Purification of DNA from agarose gels

Summary We describe a rapid and easily reproducible modification of the freeze-squeeze method of separating DNA from agarose gels. Our method involves slicing out the agarose gel portion which contains the DNA of interest, freezing this gel slice at –20°C, then centrifuging the frozen slice in a filtration unit which contains a cellulose acetate filter. The agarose is retained on the filter and the filtrate contains the DNA. DNA purified in this manner could be completely digested with restriction endonucleases and completely ligated with DNA ligase, without further purification. The percentages of recovery for various sizes of linear and plasmid double-stranded DNA ranged from 57 to 69%. The procedure takes less than 30 minutes to perform.     

Simple DNA elution from agarose gels

We developed a simple DNA elution method from agarose gels. After electrophoresis of DNA in an agarose gel, the DNA fragment to be recorved was excised out of gel with a scalpel. The excised gel was placed in the middle of small Parafilm piece, and the Parafilm was folded over the gel piece. Using the petriplate, or thumb, the gel piece was pressed between the Parafilm. Upon squeezing, the DNA inside of the gel gets extruded along with the buffer. The droplets were collected with a pipet. The DNA was then purified by conventional phenol: chloroform extraction method. Typical yields are greater than 50% as determined by UV absorbance.     

Recovery of DNA segments from agarose gels

After electrophoresis, DNA can be efficiently recovered by solubilization of agarose gels with NaClO₄, followed by retention of DNA on glass fiber filters. After removal of the NaClO₄ by ethanol, the DNA can be extracted with a low salt buffer.     

Rapid isolation of high-molecular-weight DNA from agarose gels

We have developed a simple, reliable, and rapid method for recovering DNA from agarose gels. While many methods for DNA extraction have already been described, few provide quantitative recovery of large DNA molecules. These procedures generally require costly apparatus, extended elution times, or considerable handling of the sample after elution. Our method employs a novel electroelution chamber constructed from acrylic plastic. Gel slices containing DNA are placed in the chamber between platinum electrodes. Voltage is applied and a continuous flow of buffer sweeps the eluted DNA from the chamber into an external receptacle. Elution is complete in 7 min. Concentrated DNA is obtained by butanol extraction and alcohol precipitation in 1 h. Recoveries, quantitated by counting radiolabeled DNA or by densitometry of analytical gels, were 94 to 100% for fragments of 4 to 50 kb. The eluted DNA was undegraded and could be digested with restriction enzymes, ligated, end-labeled, or used to transform cells as efficiently as noneluted DNA. Complete elution of a 100-kb plasmid, a 194-kb concatemer of bacteriophage lambda, and of 440- and 550- chromosomes of Saccharomyces cerevisiae was also achieved using the same process. This method is suitable for routine use in a wide range of cloning applications, including the electrophoretic isolation of large DNA molecules.     

Recovery of DNA from agarose gels using a modified Elutrap.

We have made a significant improvement in the electroelution device, Elutrap (Schleicher and Schuell) by substituting an agarose gel barrier, which is made from 0.6% agarose (SeaKem GTG; FMC Corporation), into the elution chamber in place of the manufacturer specified BT2 membrane. This modification substantially increases the DNA recovery from agarose gels, even in samples containing less than 1 microgram of DNA, and shortens elution times particularly for large sizes of DNA (greater than 4.4 kbp). Additionally, the gel barrier provides a reproducible quantity and quality of DNA recovery. The high quality of the eluted DNA using the modified Elutrap makes this system suitable for further DNA manipulations.     

A rapid method for extracting DNA from agarose gels

A method for obtaining high recovery of deoxyribonucleic acid (DNA) from agarose gels using an agarase extraction procedure is presented. This DNA is physically intact and biologically active. The DNA obtained with this procedure should be useful for a wide range of applications.     

Simultaneous electroelution and concentration of DNA fragments from agarose gels

A rapid and inexpensive method for the electroelution of DNA fragments from agarose gels is described. DNA fragments were separated by agarose gel electrophoresis and visualized by staining with ethidium bromide. Selected DNA fragments were placed into electroeluter tubes capped with dialysis membrane and electroeluted into a small volume of buffer using a conventional horizontal gel electrophoresis apparatus. The method successfully eluted and concentrated DNA fragments with molecular weights ranging from 2.7 to 13.9 MDa in 3 h.     

Electroelution of DNA and protein from polyacrylamide and agarose gels

An electroelution method is described for the recovery of DNA and protein from agarose or polyacrylamide gels. The samples to be electroeluted are compartmentalized in a modified microcentrifuge tube fitted with dialysis membranes. This procedure is simple, rapid, inexpensive and efficient. Within 30 min to 2 hrs, the recovery of the sample is nearly quantitative. DNA fragments recovered can be directly subjected to DNA sequence analysis or enzymatic reactions after ethanol precipitation. Proteins can also be recovered after separation by acrylamide gel in the presence or absence of detergents and be ready for further analysis.     

Optimized centrifugation for rapid elution of DNA from agarose gels

A simple method has been developed for the isolation of DNA from agarose gels. Centrifugation in a low-cost device for 45 s at low speed provides a high yield of DNA suitable for further manipulation by restriction enzymes, T₄ DNA ligase, Taq polymerase, Klenow fragment, and T₄ polynucleotide kinase, and also for sequencing. In contrasr, centrifugation for > 1 min leads to coelution of substances that inhibit DNA ligase.     

Electrophoresis of DNA in oriented agarose gels

Oriented agarose gels were prepared by applying an electric field to molten agarose while it was solidifying. Immediately afterwards, DNA samples were applied to the gel and electrophoresed in a constant unidirectional electric field. Regardless of whether the orienting field was applied parallel or perpendicular to the eventual direction of electrophoresis, the mobilities of linear and supercoiled DNA molecules were either faster (80% of the time) or slower (20% of the time) than observed in control, unoriented gels run simultaneously. The difference in mobility in the oriented gel (whether faster or slower) usually increased with increasing DNA molecular weight and increasing voltage applied to orient the agarose matrix. In perpendicularly oriented gels linear DNA fragments traveled in lanes skewed toward the side of the gel; supercoiled DNA molecules traveled in straight lanes. If the orienting voltage was applied parallel to the direction of electrophoresis, both linear and supercoiled DNA molecules migrated in straight lanes. These effects were observed in gels cast from different types of agarose, using various agarose concentrations and two different running buffers, and were observed both with and without ethidium bromide incorporated in the gel. Similar results were observed if the agarose was allowed to solidify first, and the orienting electric field was then applied to the gel for several hours before the DNA samples were added and electrophoresed. The results suggest that the agarose matrix can be oriented by electric fields applied to the gel before and probably during electrophoresis, and that orientation of the matrix affects the mobility and direction of migration of DNA molecules. The skewed lanes observed in the perpendicularly oriented gels suggest that pores or channels can be created in the matrix by application of an electric field. The oriented matrix becomes randomized with time, because DNA fragments in oriented and unoriented gels migrated in straight lanes with identical velocities 24 hours later.     

A freeze-squeeze method for recovering long DNA from agarose gels

Long DNA can be recovered from agarose gels after electrophoresis by freezing the gel slices and manually squeezing out liquid containing the DNA. With this method the recoveries of phage T₇ DNA (molecular weight 25 × 10⁶) and the open and closed forms of circular phage PM2 DNA (molecular weight 6 × 10⁶) were about 70%. Sedimentation analysis shows that the extruded DNA has not sustained double- or single-stranded breaks. The extruded DNA can be used without further purification as substrate for the restriction endonuclease Hind_II,III, from Hemophilus influenzae, for DNA·DNA hybridization and for electron microscopy.     

A method for the recovery of DNA from agarose gels.

We describe a quick and versatile method for the isolation of DNA from agarose gels. The DNA is electrophoresed into a trough containing hydroxyapatite, where it is bound. The hydroxyapatite is taken out and the DNA eluted with phosphate buffer. By putting the hydroxyapatite on a small column of Sephadex G50, elution and subsequent removal of phosphate can be performed in one step. The DNA recovered can be used equally well in enzymatic incubations as DNA not purified through agarose gel electrophoresis. Several applications of this technique are described.     

Rapid transfer of DNA from agarose gels to nylon membranes.

The unique properties of nylon membranes allow for dramatic improvement in the capillary transfer of DNA restriction fragments from agarose gels (Southern blotting). By using 0.4 M NaOH as the transfer solvent following a short pre-treatment of the gel in acid, DNA is depurinated during transfer. Fragments of all sizes are eluted and retained quantitatively by the membrane; furthermore, the alkaline solvent induces covalent fixation of DNA to the membrane. The saving in time and materials afforded by this simple modification is accompanied by a marked improvement in resolution and a ten-fold increase in sensitivity of subsequent hybridization analyses. In addition, we have found that nylon membrane completely retains native (and denatured) DNA in transfer solvents of low ionic strength (including distilled water), although quantitative elution of DNA from the gel is limited to fragments smaller than 4 Kb. This property can be utilized in the direct electrophoretic transfer of native restriction fragments from polyacrylamide gels. Exposure of DNA to ultraviolet light, either in the gel or following transfer to nylon membrane, reduces its ability to hybridize.     

Rapid purification of DNA from agarose gels by centrifugation through a disposable plastic column

A simple and rapid method for purifying DNA from agarose gels is described. Agarose slices containing DNA are placed in a disposable plastic column and the DNA is separated from the agarose by centrifugation in a microfuge. Recoveries averaging 25% are obtained for DNA of 14 kb or less. The recovered DNA can be labeled to high specific activity, cleaved with restriction endonucleases, and ligated efficiently using standard cloning vectors.     

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.