A simple method for filter hybridization of labeled restriction fragments excised from gels

Labeled DNA restriction fragments excised from agarose or bisacrylylcystamine-acrylamide gels can be used for hybridization to nitrocellulose-bound DNA without eliminating the gel matrix. A gel slice containing the labeled fragment is excised, dissolved by heating at 105 degrees C (in the presence of beta-mercaptoethanol for bisacrylylcystamine-acrylamide gels), and added to the hybridization mixture. The presence of agarose or polyacrylamide in the solution does not inhibit hybridization. The method is simple, rapid, and allows complete recovery of the probe.     

A method for eluting DNA in a wide range of molecular weights from agarose gels

We have developed a simple and rapid method for recovering DNAs of a wide range of molecular weights from agarose gels. A DNA-containing gel slice is placed on a Parafilm sheet in the center of a circular (positive) electrode and covered with a drop of buffer, while a linear (negative) electrode is placed on the top of the gel and driven about 1 mm into the gel itself. When a continuous current is applied, the DNA migrates into the buffer toward the circular electrode. We have obtained almost total recovery of DNAs up to 10 kb in size. Our method may also be used, under appropriate conditions, for higher molecular weight DNAs. The yield and all the biological assays performed on the DNAs obtained by our method recommend it for routine laboratory use.     

Transformation of mammalian cells with recombinant DNA directly from Seaplaque agarose

Transfection of African green monkey kidney cells directly with recombinant DNA excised from, but still present in, Seaplaque agarose after electrophoresis, is described. Efficiencies of transfection increased by 30% when the gel was present compared with transfection in the absence of the agarose. Extraction of the DNA from the gel was not necessary, thereby obviating a purification step and the concomitant losses. To generate recombinant molecules bacterial plasmid sequences are not necessary, thereby reducing considerably the size of the recombinant molecule and removing extraneous and deleterious sequences, e.g., "poison sequences." Linear or circular DNA molecules could be transfected in the melted and diluted agarose with the same ease as in its absence. Hence linear partial ligation products can be excised from the gel after electrophoresis to generate recombinant DNA molecules directly in mammalian cells.     

Pellet pestle homogenization of agarose gel slices at 45 degrees C for deoxyribonucleic acid extraction

A simple method for extracting DNA from agarose gel slices is described. The extraction is rapid and does not involve harsh chemicals or sophisticated equipment. The method involves homogenization of the excised gel slice (in Tris-EDTA buffer), containing the DNA fragment of interest, at 45 degrees C in a microcentrifuge tube with a Kontes pellet pestle for 1 min. The "homogenate" is then centrifuged for 30 s and the supernatant is saved. The "homogenized" agarose is extracted one more time and the supernatant obtained is combined with the previous supernatant. The DNA extracted using this method lent itself to restriction enzyme analysis, ligation, transformation, and expression of functional protein in bacteria. This method was found to be applicable with 0.8, 1.0, and 2.0% agarose gels. DNA fragments varying from 23 to 0.4 kb were extracted using this procedure and a yield ranging from 40 to 90% was obtained. The yield was higher for fragments 2.0 kb and higher (70-90%). This range of efficiency was maintained when the starting material was kept between 10 and 300 ng. The heat step was found to be critical since homogenization at room temperature failed to yield any DNA. Extracting DNA with our method elicited an increased yield (up to twofold) compared with that extracted with a commercial kit. Also, the number of transformants obtained using the DNA extracted with our method was at least twice that obtained using the DNA extracted with the commercial kit.     

Electroeluting DNA Fragments

Purified DNA fragments are used for different purposes in Molecular Biology and they can be prepared by several procedures. Most of them require a previous electrophoresis of the DNA fragments in order to separate the band of interest. Then, this band is excised out from an agarose or acrylamide gel and purified by using either: binding and elution from glass or silica particles, DEAE-cellulose membranes, "crush and soak method", electroelution or very often expensive commercial purification kits. Thus, selecting a method will depend mostly of what is available in the laboratory. The electroelution procedure allows one to purify very clean DNA to be used in a large number of applications (sequencing, radiolabeling, enzymatic restriction, enzymatic modification, cloning etc). This procedure consists in placing DNA band-containing agarose or acrylamide slices into sample wells of the electroeluter, then applying current will make the DNA fragment to leave the agarose and thus be trapped in a cushion salt to be recovered later by ethanol precipitation.     

Dried gel hybridization in place of Southern hybridization for detection of Listeria monocytogenes DNA fragments

A simple, sensitive, dried gel DNA hybridization method for detection of Listeria monocytogenes DNA fragments is described. DNA samples were fractionated on an agarose gel. The gel was then denatured in NaOH-NaCl and neutralized in Tris-NaCl. The resulting agarose gel was dried and hybridized with 32P-labelled DNA probe. No transfer to nitrocellulose membranes was used.     

A simple and fast electrophoretic method for elution of nucleic acids from gels

A very convenient electrophoretic procedure for DNA or RNA elution from agarose or polyacrylamide gels is described. The gel piece with nucleic acid to be eluted is contained in a dialysis bag filled with buffer and elution is carried out in a horizontal electrophoresis apparatus. The nucleic acid is recovered with a high yield and can be used, without prior treatment, in further enzymatic or chemical reactions. Results obtained with DNA are presented here.     

Separation of yeast chromosome-sized DNAs by pulsed field gradient gel electrophoresis

A new type of gel electrophoresis separates DNA molecules up to 2000 kb with resolutions exceeding the logarithmic molecular weight dependence of conventional electrophoresis. The technique uses 1.5% agarose, 10 to 20 micrograms of DNA per well, and low ionic strength buffers. It employs alternately pulsed, perpendicularly oriented electrical fields, at least one of which is inhomogeneous. The duration of the applied electrical pulses is varied from 1 sec to 90 sec to achieve optimal separations for DNAs with sizes from 30 to 2000 kb. This pulsed field gradient gel electrophoresis fractionates intact S. cerevisiae chromosomal DNA, producing a molecular karyotype that greatly facilitates the assignment of genes to yeast chromosomes. Each yeast chromosome consists of a single piece of DNA; the chromosome sizes are consistent with the genetic linkage map. We also describe a general method for preparing spheroplasts, and cell lysates, without significant chromosomal DNA breakage.     

一种有效回收小分子DNA片段的方法

介绍了一种有效回收小于200bp DNA片段的方法。用改进的冻融-离心回收法对155bp的DNA片段进行回收,并且与常规冻融-离心回收、TaKaRa回收试剂盒的结果做对比,用琼脂糖凝胶电泳检测回收结果,紫外吸收法定量分析。结果证明:改进的方法是一种经济、方便、可靠的回收小分子DNA片段的方法。     

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.     

Shotgun polymerase chain reaction: construction of clone libraries specific to a NotI fragment of flow-sorted human chromosome 22.

We have developed the "shotgun polymerase chain reaction," a method for obtaining a large number of DNA markers specific to a giant DNA fragment, which facilitates analysis of a particular chromosomal region. We applied this method to a giant NotI fragment which carries the immunoglobulin lambda constant region on chromosome 22. NotI digests of chromosome 22 flow-sorted from human B-lymphoblastoid cell line GM130B were size fractionated by pulsed-field gel electrophoresis. Preliminary Southern hybridization analysis revealed that the immunoglobulin lambda constant region was conveyed on 1.4- and 1.3-Mb NotI fragments in this cell line. The agarose gel corresponding to 1.2 to 1.5 Mb in size was excised into slices and subjected to polymerase chain reaction to identify gel slices containing NotI fragments carrying Ke-Oz+, a subtype of the immunoglobulin lambda constant region. From the NotI fragment thus identified, a large number of small DNA segments were amplified through the ligation-mediated random polymerase chain reaction method. The amplified products were cloned and analyzed for chromosomal origin and localization to particular NotI fragments. Seven of eighteen clones originated from the 1.4-Mb NotI fragment of chromosome 22 in GM130B cells, which appears to be exactly the same as detected by a probe for the immunoglobulin lambda constant region.     

一种适合于烟粉虱产卵的新型人工膜系统

介绍一种适合烟粉虱Bemisia tabaci(Gennadius)产卵的新型人工膜系统。该系统由一个透明的塑料盒,底直径30mm,顶口直径40mm,深35mm,其上覆盖1层或2层Parafilm M膜,与产卵的成虫相接触的1层厚度为5~8μm,2层膜中间或单层膜上加试验所需的试剂。将膜装置放于不透光的容器上,其上覆盖黄色玻璃纸,以吸引烟粉虱产卵。该装置可用于烟粉虱的人工产卵,观察卵的发育及研究相关的生理机制。     

PCR特异产物回收纯化方法的比较

方法：采用三种方法对苹果褪绿叶斑病毒RT-PCR的特异DNA产物进行回收纯化。目的：针对不同情况,选择适宜的回收纯化方法。结果：用普通琼脂糖替代低融点琼脂糖,回收纯化后产物的浓度及纯度与低融点琼脂糖法基本一致,完全可以用普通琼脂糖替代低融点琼脂糖进行DNA片段的回收纯化,从而降低成本,简化操作。玻璃奶法的回收纯度明显高于低融点琼脂糖法和普通琼脂糖法,且更快速安全,是采用普通琼脂糖法还是采用玻璃奶法回收纯化DAN片段应以实际需要而定。     

Single long DNA molecule analysis using fluorescence microscopy.

Single long DNA molecule (T4 DNA) in agarose gel was visualized with a fluorescence microscope. We confirmed alternating current electric fields is effective for stretching of single DNA molecule in agarose gel. This stretching phenomenon was observed with wide range of agarose gel concentration from 0.5%(W/V) to 1.5%. From this observation, the presence of agarose gel fiber is essential for this stretching phenomenon. The stretching process of several DNA molecules in gel shows discontinuity, which is never observed in polymer systems. It would be based on topological restriction from gel fibers.     

Molecular Stretching of Long DNA in Agarose Gel Using Alternating Current Electric Fields

We demonstrate a novel method for stretching a long DNA molecule in agarose gel with alternating current (AC) electric fields. The molecular motion of a long DNA (T4 DNA; 165.6 kb) in agarose gel was studied using fluorescence microscopy. The effects of a wide range of field frequencies, field strengths, and gel concentrations were investigated. Stretching was only observed in the AC field when a frequency of ∼10 Hz was used. The maximal length of the stretched DNA had the longest value when a field strength of 200 to 400 V/cm was used. Stretching was not sensitive to a range of agarose gel concentrations from 0.5 to 3%. Together, these experiments indicate that the optimal conditions for stretching long DNA in an AC electric field are a frequency of 10 Hz with a field strength of 200 V/cm and a gel concentration of 1% agarose. Using these conditions, we were able to successfully stretch Saccharomyces cerevisiae chromosomal DNA molecules (225-2,200 kb). These results may aid in the development of a novel method to stretch much longer DNA, such as human chromosomal DNA, and may contribute to the analysis of a single chromosomal DNA from a single cell.     

一种用于PCR模板制备的电泳产物简易回收方法

为了探索一种简便、有效而且能从琼脂糖凝胶中大量回收用于第2次PCR扩增的DNA电泳条带的方法,采用刀片切胶法和牙签插胶法从琼脂糖中回收DNA,并进行了两种方法的比较．结果显示牙签插胶法回收的DNA用作第2次PCR的模板,获得了清晰、稳定的PCR产物电泳条带,用该法成功地制备了一批DNA微阵列探针．由此可见牙签插胶法是一种简便、快速、有效的用于PCR模板的DNA琼脂糖凝胶回收法．     

Measurement of DNA length by gel electrophoresis. I. Improved accuracy of mobility measurements using a digital microdensitometer and computer processing

The electrophoretic mobilities of DNA polymer fragments in an agarose gel have been measured from a photograph of the gel by different methods and converted to lengths by the reciprocal method. The method of measurement can introduce large errors in the length estimates. The use of a digital microdensitometer to obtain optical density profiles of gel tracks with subsequent computer processing to find peak positions was found to give the most accurate DNA lengths.     

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.     

Transverse agarose pore gradient gel electrophoresis of DNA.

Transverse agarose pore gradient gels were prepared on GelBond in the concentration range of nominally 0.2-1.5% SeaKem GTG agarose, using density stabilization by glycerol and incorporation of a dye to define the gel concentration at each point on the pore gradient gel. The distribution of the dye was evaluated by photography, video-acquisition and digitization of the gradient mixture and by densitometry of the gel. The gel was applied to the electrophoresis of a 1-kb standard ladder of DNA fragments, using standard submarine apparatus. The method extends to agarose gel electrophoresis the benefits of semi-automated analysis of 'Ferguson curves' described in application to polyacrylamide gel by Wheeler et al. (J. Biochem. Biophys. Methods 24, 171-180).     

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.