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.     

Semi-dry electroblotting of DNA

A procedure is described for the rapid transfer of DNA from agarose gels to nylon membranes using the semi-dry electroblotting technique. A Hind III digest of lambda DNA which was separated in a 1% agarose gel containing Tris, Borate, and EDTA (pH 8.0) was employed for the electrotransfer experiments. Transfer efficiency was determined by staining the DNA on the nylon membranes with a colloidal iron reagent. Current densities of 3-5 mA/sq. cm of gel permitted the transfer of high (23 kb) and low (0.3 kb) molecular weight fragments within 15 min. However, efficient transfer required a high ionic strength buffer that would prevent uneven dehydration of the agarose gel. Critical parameters for the transfer of nucleic acids with the semi-dry technique are discussed.     

Electrophoretic elution of nucleic acids from acrylamide and agarose gels

A simple method for electrophoretic elution of nucleic acids from gel slices is described. The procedure utilizes a standard tube gel system and can be completed in as little as one hour. Nucleic acids are recovered in a small volume with almost 100% efficiency. The procedure is applicable equally to acrylamide and agarose gels, and small as well as large RNA and DNA molecules. The eluted nucleic acids are essentially undegraded and are suitable for a variety of structural and biological analyses.     

Restriction endonuclease mapping by crossed contact hybridization: the ribosomal RNA genes of Achlya ambisexualis.

A rapid, convenient and economical method for the hybridization of electrophoretically resolved RNA to DNA restriction fragments immobilized on nitrocellulose filters is described. DNA was digested, electrophoresed on agarose gels in a wide band and transferred to a nitrocellulose filter. The filter was then placed on the surface of a second gel containing radioactively labeled RNA electrophoresed under denaturing conditions in a similar way. The filter and gel were oriented so that the DNA and RNA bands were perpendicular to one another and the RNA was transferred from the gel through the filter under conditions which promote RNA-DNA hybridization. Following washing, the filter was autoradiographed. RNA-DNA sequence relationships could be conveniently determined from the spots produced at regions of intersection of homologous nucleic acids. The two dimensional array formed in this procedure fascilitates the rapid ordering of DNA restriction fragments. An example of its use for this purpose is presented.     

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.     

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.     

Rapid agarose gel electrophoretic mobility shift assay for quantitating protein: RNA interactions

Interactions between proteins and nucleic acids are frequently analyzed using electrophoretic mobility shift assays (EMSAs). This technique separates bound protein:nucleic acid complexes from free nucleic acids by electrophoresis, most commonly using polyacrylamide gels. The current study utilizes recent advances in agarose gel electrophoresis technology to develop a new EMSA protocol that is simpler and faster than traditional polyacrylamide methods. Agarose gels are normally run at low voltages (∼10 V/cm) to minimize heating and gel artifacts. In this study we demonstrate that EMSAs performed using agarose gels can be run at high voltages (≥20 V/cm) with 0.5 × TB (Tris-borate) buffer, allowing for short run times while simultaneously yielding high band resolution. Several parameters affecting band and image quality were optimized for the procedure, including gel thickness, agarose percentage, and applied voltage. Association of the siRNA-binding protein p19 with its target RNA was investigated using the new system. The agarose gel and conventional polyacrylamide gel methods generated similar apparent binding constants in side-by-side experiments. A particular advantage of the new approach described here is that the short run times (5–10 min) reduce opportunities for dissociation of bound complexes, an important concern in non-equilibrium nucleic acid binding experiments.     

Methods for recovering nucleic acid fragments from agarose gels

Agarose gel electrophoresis is a powerful technique for the separation of nucleic acids on the basis of their size and conformation. The development of methods to recover size-fractionated nucleic acids molecules from agarose gels has greatly facilitated recombinant DNA technologies. Although several methods for recovering DNA and RNA molecules have been developed during the past fifteen years, none of them has been universally accepted. In this review we describe, discuss and evaluate the most common procedures with which we have had experience. Our evaluation is based on the criteria of yield, purity, speed, simplicity and low cost. We have considered three different approaches to the problem of recovering nucleic acids: chemical gel dissolution, physical gel disruption and physical extrusion from intact gels.     

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.     

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.     

Preparation of GDP-D-mannose specifically labeled with tritium in the D-mannosyl moiety

A method, called “bidirectional transfer”, has been described for the transfer of DNA and RNA from agarose or polyacrylamide gels onto diazobenzyloxymethyl (DBM)-paper or nitrocellulose filters. The gels were sandwiched between either two nitrocellulose filters or two diazobenzyloxymethyl-papers. Next, the nucleic acids were allowed to diffuse out of the gels onto the filters. In this way, duplicate blots were obtained from a single gel. The bidirectional transfer of DNA or RNA from 0.5 to 1% agarose gels was complete and nearly quantitative after 1 h of transfer. DNA fragments from 5% polyacrylamide gels were efficiently blotted after 36 h onto nitrocellulose filters using bidirectional transfer. The fragments were transferred with good resolution and were shown to be efficient substrates for homologous [³²P]DNA probes.     

Isotachophoresis of nucleic acids in agarose gel rods

A new method of electrophoresis (isotachophoresis in agarose gel rods) in which nucleic acid molecules are not separated but, oppositely, are brought together into one band, was elaborated. Heterogeneous in size DNA and RNA polymers present in a few milliliters of a solution at so low concentration that their isolation by other methods is hardly attainable and fraught with losses are brought together into one visible narrow band when put in a discontinuous electric field. Polynucleotides migrate in dilute (0.1%) semifluid agarose gel that permits easy quantitative isolation of the band of interest. Resulting DNA can be used directly in PCR. The suggested method for isolation of micro amounts of nucleic acids from dilute solutions can be applied to forensic and clinical research and cancer gene diagnostics by the analysis of fragmented circulating DNA from bodily fluids.     

Detection of sickle-cell mutation by electrophoresis of partial RNA:DNA hybrids following solution hybridization

We have developed a method in which partially single-stranded (ss) DNA molecules containing a defined region of duplex RNA:DNA are electrophoretically separated in agarose gels. The partial hybrids are formed by solution hybridization with a uniform length RNA probe complementary to part of the DNA sequence of interest. Following hybridization, the RNA/DNA mixture is fractionated by agarose gel electrophoresis at high temperature to minimize intrastrand base pairing which causes mobility heterogeneity. Not requiring the steps of DNA transfer from the gel to a solid support and subsequent probing, pre-electrophoretic hybridization allows the direct identification of single-copy fragments. Conditions for the detection of single-copy genes in human DNA digested with specific restriction endonucleases were developed and applied to the diagnosis of sickle-cell disease. This method should be applicable for the analysis of DNAs of high complexity where the presence of DNA polymorphisms and interspersed repeated DNA sequences often make impossible the creation of complete RNA:DNA hybrids.     

Electrophoretic strand separation of long DNAs with poly (U,G) in agarose gels.

We have found that binding of poly(U,G) to single-stranded DNA decreases its mobility in 0.3% agarose gels. Differential binding to the complementary strands of denatured duplex DNA provides a simple method for strand separation. The method is shown to work with bacteriophage lambda DNA, adenovirus DNA and mtDNA for Tetrahymena pyriformis. In all cases the strand that binds more poly(U,G) in CsCl gradients also binds more in gels. The separated strands can be directly blotted from the gel onto nitrocellulose filters and used for hybridization experiments.     

Purification of 5S RNA from Plant Leaves

A simple and rapid method for large scale preparation of 5S RNA from plant leaves is described. To begin, all nucleic acids were extracted from the leaves with a mixture of phenol-chloroform-n-butyl alcohol and extracting buffer. After precipitation of the high-molecular-weight nucleic acids from the crude extract with 2 M LiCl, the low, molecular-weight RNA in the supernatant (containing about 6% 5S RNA) could be separated by eleetrophoresis on denatured polyaerylamide gels. The band of 5S RNA was excised from the preparatory slab gel under UV light and then purified by eleetrophoretie elution. In our experiments, several mg pure 5S RNA was obtained from 100 g leaves in a single run which takes about 4 days. The purified final produet was pure as showing a single hand on denatured polyaerylamide gel and a typical UV absorption peak of nucleic acid. The sedimentation coefficient (S20w) of the product was 4.6 as determined by ultracentrifugation.     

Isolation and separation of nucleic acids from Streptomyces hydrogenans (author's transl)]

Different methods for homogenization of cells of Streptomyces hydrogenans, for extraction of nucleic acids and for fractionation of the RNA and DNA obtained were critically examined. The only way to prepare high molecular weight rapidly labelled RNA and polysomes was to grind freeze-dried cells together with kieselguhr with a mortar and pestle. The best results for extraction of nucleic acids from the cell homogenate were obtained in the presence of diethyl pyrocarbonate (diethyl oxydiformate), yielding nucleic acids of considerable purity in a minimal amount of time. The best resolution of extracted nucleic acids was achieved by electrophoresis in 2% agarose acrylamide gels. This technique proved that during the cell homogenization and extraction procedure the bulk of nucliec acids was not degraded to low molecular weight material. An improved device for the registration of the profile of the absorption after gel electrophoresis is described.     

Hybridization of DNA to RNA in methylmercuric hydroxide agarose gels

We describe a method for hybridization of cDNA probes to RNA directly in agarose gels which provides a practical alternative to methods involving transfer of the RNA out of the gel. Total cellular RNA is subjected to electrophoresis in agarose gels containing methylmercuric hydroxide as the denaturing agent. After removal of the methylmercuric hydroxide, the gel is dried and 32P-labeled DNA probes are hybridized to the immobilized RNA. This method is more economical in time and expense than methods involving transfer of the RNA out of the gel, while maintaining a level of sensitivity comparable to other procedures.     

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.     

Nonradioactive method to detect native single-stranded G-tails on yeast telomeres using a modified Southern blot protocol

Because of their low abundance and short length, telomeric single-stranded extensions have not traditionally been assessed by Southern blot analysis. Instead, most methods have relied on hybridizing radioactively labeled oligonucleotide probes to electrophoresed DNA within agarose gels. Here we describe a rapid and nonradioactive Southern blot-derived method to transfer and detect telomeric single-stranded G-rich overhangs (G-tails) under nondenaturing (native) conditions, using Saccharomyces cerevisiae DNA. Restriction enzyme-digested chromosomal DNA is separated by agarose gel electrophoresis, transferred onto a charged membrane by electroblotting under nondenaturing conditions, and probed with a digoxigenin (DIG)-labeled oligonucleotide. Compared with the prolonged film exposure required to detect radioactive probes, detection of short single-strand G-tails with this method takes mere minutes. Furthermore, following detection of the single-stranded G-tails, the DNA on the membrane can be denatured and reprobed using conventional hybridization and detection methods.     

SELECTIVE RETENTION AND FILTRATION OF BRAIN NUCLEIC ACIDS IN AGAROSE GELS

Abstract— Total nucleic acids of rat brain have been separated by agarose gel chromatography at 2 m -NaCl into DNA. transfer RNA plus low molecular weight RNA. and high molecular weight RNA fractions. The DNA fraction contained less than 1 per cent RNA by weight judged by either short-term or long-term labelling with ortho[³²P]phosphate. The high molecular weight RNA fraction contained 28 s and 18 s ribosomal RNAs and a heterogeneous population of 20-60 s RNAs, apparent after short-term labelling and characterized by a high content of nearest-neighbour-labelled uridylic acid. The rapidly sedimenting (>30 s ) portion of these RNAs could be largely separated from ribosomal RNAs by gel filtration using 4% agarose. The ribosomal RNAs could be fully resolved into 28 s and 18 s components by agarose gel chromatography at 0.5 m -0.6 m -NaCl, as shown by analysis of their sedimentation and nucleotide composition.