One-hour downward alkaline capillary transfer for blotting of DNA and RNA.

The downward alkaline capillary transfer of DNA and RNA from agarose gel to a hybridization membrane was performed using a transfer solution containing 3 M NaCl and 8 mM NaOH. Under mild alkaline conditions, DNA and RNA were completely eluted from the agarose gel and bound to a hybridization membrane within 1 h. On the basis of this new method of transfer a blotting protocol, downward alkaline blotting, was elaborated. It provides a fast and efficient alternative to commonly used Southern and Northern blotting protocols. The downward alkaline blotting of DNA and RNA can be completed in 2.5 and 1.5 h, respectively, and can be used with both plastic and nitrocellulose membranes. In addition, the downward alkaline blotting protocol allows for a hybridization efficiency of DNA and RNA higher than that of the standard blotting protocols performed at neutral pH.     

Denaturing RNA electrophoresis in TAE agarose gels

Current methods of analytical RNA electrophoresis are based on the utilization of either complicated laboratory instrumentation or toxic, carcinogenic, or expensive chemicals. We suggest here the use of classical Tris-acetate-ethylenediamine tetraacetic acid (TAE) agarose gels combined with prior denaturation of RNA samples in hot formamide for the electrophoretic separation of RNA species. We present a brief comparison of the proposed TAE/formamide method with the most common 3-(N-morpholino)propanesulfonic acid/formaldehyde agarose gel protocol and show that both methods produce comparable results for size determination of RNA molecules and subsequent Northern blotting of gels. In addition to purified RNA samples, the robustness of the TAE/formamide protocol is demonstrated by its suitability for the analysis of RNA quality in crude yeast cell lysates containing large amounts of proteins, DNA, and other contaminating molecules. We therefore propose the TAE/formamide agarose electrophoresis as a rapid, simple, and cheaper alternative to current methods of RNA electrophoresis. Additionally, another benefit is the reduced exposure of laboratory personnel to hazardous chemicals.     

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.     

Rapid alkaline transfer of low molecular weight DNA from NuSieve GTG agarose gels

The rapid alkaline transfer of high molecular weight DNA from agarose gels to nylon membranes has greatly decreased the time required for setup of Southern transfers. This technique has been used to resolve genomic DNA greater than 1000 base pairs by conventional electrophoresis on 1% agarose gels followed by alkaline transfer to nylon membrane. Now we report that this rapid alkaline method can be used for the transfer of low molecular weight DNA fragments (10 to 1000 base pairs) from NuSieve GTG agarose gels to nylon membrane.     

A procedure for DNA and RNA transfer to membrane filters avoiding weight-induced gel flattening.

We describe a technique of rapid (within 1-2 h) transfer of DNA and RNA from agarose gels to nitrocellulose or nylon membrane filters. It is characterized by nearly complete elimination of mechanical action on the gel (a thin layer of liquid is placed over the gel and, filtering through the gel into a stack of paper towels beneath, it transfers nucleic acids onto the filter under the gel). This "descending" transfer, as opposed to the widely used "ascending" Southern transfer, reduces the transfer time (to about 1 h) with equal or higher quality of the hybridization signal. The comparison of transfer kinetics by the both methods shows that (a) the Southern transfer of large size DNA fragments proceeds quicker than it has been thought so far and is almost complete within 4 h; (b) the descending transfer has an advantage over the ascending one in the rate of transfer (1-2 h) and its efficiency; and (c) the time of transfer may become a critical parameter upon using a filter with an apparently low retention capacity (Hybond N, Amersham) that is manifested by a decreased signal at longer than optimal transfer times.     

Cloning, restriction digestion and DNA labeling of large DNA fragments (greater than or equal to 1 kb) in the presence of remelted SeaPlaque GTG agarose gels.

Large DNA fragments (greater than or equal to 1 kb), separated in low melting temperature SeaPlaque GTG agarose gels, can be enzymatically processed directly in the presence of this agarose (in-gel). Time saving protocols are discussed for in-gel processing of large DNA fragments in the presence of remelted SeaPlaque GTG agarose, including cloning into pUC18, nick translation, random priming and restriction digestion. These in-gel molecular biology techniques are as efficient as those using DNA recovered from agarose. The effects of UV irradiation, Mg2+ concentration and agarose concentration on selected in-gel protocols are also discussed.     

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.     

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.     

Hybridization of nucleic acids directly in agarose gels

Nucleic acids, both DNA and RNA, separated on agarose gels can be visualized by direct hybridization of the dried gel with appropriate radioactive probes. This method does not involve the transfer of the nucleic acid from the gel. The method requires less manipulation than other procedures; it is extremely rapid, sensitive, and inexpensive. These attributes make this procedure a valuable alternative or supplement to the commonly used methods for visualization by hybridization of nucleic acids separated on agarose gels.     

Northern blot mapping: a procedure for mapping mRNA immobilized on nitrocellulose by probing with end-labeled DNA fragments

A simple method for mapping RNA on a Northern blot with a mixture of end-labeled DNA fragments is described. The DNA fragments are labeled either in 5' or in 3' directly after digestion by restriction enzyme(s) and used without any further purification step as probe to hybridize a Northern blot. After autoradiography, the DNA fragments hybridized to each mRNA species are recovered by heating the nitrocellulose and analyzed on denaturing polyacrylamide or agarose gels. This method indicates which DNA fragment hybridizes with which mRNA species and requires far fewer different manipulations than successive hybridization of a Northern blot with several nick-translated purified DNA fragments.     

A rapid method for determining the relationship between cDNA clones

We describe a technique for rapidly screening the inserts of plasmids for homology to each other by using DNA fragments isolated in agarose gels to probe Southern blots of DNA prepared by the "miniprep" alkaline lysis method. The procedure includes a technique for labeling DNA fragments in agarose gel slices without further purification. The protocol results in a significant savings in time and expense and a considerable increase in fragment yield over methods involving fragment purification from polyacrylamide or agarose gels.     

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.     

An improved method for Southern DNA and Northern RNA blotting using a Mupid-2 Mini-Gel electrophoresis unit

An improved method for Southern DNA and Northern RNA blotting using the Mupid-2 Mini-Gel System is described. We get sharp and clear bands in Southern and Northern blotting after only 30 min short gel electrophoresis instead of the several hours large gel electrophoresis of conventional methods. The high electrical voltage with a pulse-like current of the Mupid-2 Mini-Gel System also allows reduction of the amount of formaldehyde, a harmful reagent, from the gel running buffer in RNA blotting. This minor modification of DNA and RNA blotting technique enables us to perform the complete experimental procedure more quickly economically in less space, than conventional Southern and Northern blotting, as well as using an extremely small amount of formaldehyde in RNA blotting.     

The presence of ovalbumin mRNA coding sequences in multiple restriction fragments of chicken DNA.

Chicken DNA has been digested with restriction enzymes and the size distribution of the DNA fragments containing ovalbumin specific sequences has been examined after separation of the fragments on agarose gels and transfer to nitrocellulose sheets. Hybridisation with terminally 32P-labelled ovalbumin mRNA fragments or with RNA populations transcribed from the DNA of a hybrid plasmid containing ovalbumin sequences was used to locate the DNA fragments coding for ovalbumin. Digestion with enzymes which do not cut within the portion of the ovalbumin gene synthesised from ovalbumin messenger RNA in vitro has shown the presence of several defined fragments carrying ovalbumin specific sequences. Possible explanations of these observations are discussed.     

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.     

Sensitivity of Prestaining RNA with Ethidium Bromide Before Electrophoresis and Performance of Subsequent Northern Blots Using Heterologous DNA Probes

Adding ethidium bromide (EtBr) at low concentrations to RNA samples before running formaldehyde–agarose gels affords the advantages of checking RNA integrity and evaluating the quality of size-separation at any time during electrophoresis or immediately after either electrophoresis or blotted the separated RNA onto the membrane without significantly compromising mobility, transfer, or hybridization. In this study, we systematically examined the factors that affect the sensitivity of RNA prestaining by heating RNA samples that include EtBr before electrophoresis under different denaturation conditions. We also examined the efficiency of the hybridization of EtBr-prestained RNA with heterologous DNA probes. The results showed that the fluorescent intensity of EtBr-prestained RNA was affected not only by the EtBr concentration as previously reported but also by the RNA amount, denaturation time, and denaturation temperature. Prior staining of RNA with 40 μg/mL EtBr significantly decreased the efficiency of Northern blot hybridization with heterologous DNA probes. We propose that to best combine staining sensitivity and the efficiency of Northern blot hybridization with heterologous DNA probes, the concentration of EtBr used to prestain RNA should not exceed 30 μg/mL. The efficiency of the hybridization of EtBr-prestained RNA was affected not only by factors that affect staining sensitivity but also by the type of probe used.     

Detection of base mutations in genomic DNA using denaturing gradient gel electrophoresis (DGGE) followed by transfer and hybridization with gene-specific probes

It has been shown that minor differences, such as single-base-pair substitutions between otherwise identical DNA fragments can result in altered melting behavior detectable by denaturing gradient gel electrophoresis (DGGE). Sequence variations in only a small DNA region within one locus can be detected using the previously described procedures. We have developed a method for the efficient Southern transfer of genomic DNA fragments from the denaturing gradient gels in order to be able to analyze larger regions in several loci for variation. The gels were made using polyacrylamide containing 2% low-geling-temperature agarose (LGT). The polyacrylamide gel (PAG) was crosslinked with a reversible crosslinker, and after electrophoresis the crosslinks were cleaved, the structure of the gel being maintained by the agarose. After this treatment of the denaturing gels, more than 90% of the DNA fragments could be transferred to nylon membranes by alkaline transfer, while electroblotting transferred only 10% of the DNA. Hybridization with gene-specific probes was then performed. We have used this technique to identify an RFLP in the COL1A2 gene in a human genomic DNA sample. The transfer technique described should make the use of DGGE more widely applicable since the genomic DNA fragments separated on one gel can be screened with several different probes, both cDNA and genomic probes.     

RNA molecular weight determination by agarose gel electrophoresis using formaldehyde as denaturant: comparison of RNA and DNA molecular weight markers

Reliable molecular weight measurements of RNA molecules as large as 4.0 X 10(6) dalton can be made on agarose gels containing 2.2 M formaldehyde as denaturant (Lehrach et al., 1977). Both eucaryotic and procaryotic ribosomal RNAs have generally been used as molecular weight markers. However, Maniatis et al. (1982) have suggested the use of restriction fragments of DNA as convenient molecular weight markers for RNA samples run in formaldehyde/agarose gels. This communication compares RNA and DNA molecular weight markers run under identical conditions.     

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.     

A quantitative model of DNA fragments generated by ionizing radiation, and possible experimental applications

We derive an equation for observed frequencies of DNA fragments as a function of size. In this derivation, we consider an experimental system where fragments are generated by random, independent double-strand breaks on chromosomes (or other large DNA molecules) and then separated by size on agarose gels. When visualizing these fragments using Southern hybridization techniques (employing a site-specific probe), we predict an intensity distribution that has unusual properties. In particular, peaks in the fragment size distribution depend not only on standard breakage parameters, but also on the location of the hybridization site. Our model is consistent with experimental and theoretical results reported elsewhere, where measurements of peaks are used for the physical mapping of genes. Further, we propose that similar experiments might be suitable for precise measurements of the parameters of double-strand breakage (as an alternative to neutral filter elutions and neutral sucrose gradients) and for testing the assumption of random, independent breakage for different types of radiation.