A mobility shift detection method for DNA methylation analysis using phosphate affinity polyacrylamide gel electrophoresis

We describe a procedure for DNA methylation analysis using the bisulfite-mediated cytosine-to-uracil conversion of a target DNA followed by methylation-specific polymerase chain reaction (MSP) and phosphate affinity polyacrylamide gel electrophoresis (PAGE). The MSP was performed using a 1:1 mixture of 5′-phosphorylated methylation-specific and 5′-OH non-methylation-specific primers. The PAGE using an immobilized phosphate-binding tag molecule (i.e., a polyacrylamide-bound dizinc(II) complex, Zn²⁺-Phos-tag), which selectively captures the 5′-phosphorylated DNA fragment, enabled the mobility shift detection of the methylation-specific product as a slower migration band. Using this novel procedure, we demonstrated the detection of a methylated cytosine base in a pUC19 plasmid.     

Analysis of polyoma virus DNA replicative intermediates by agarose gel electrophoresis.

Agarose gel electrophoresis has been used to fractionate polyoma virus DNA replicative intermediates (RI) according to maturity. Approximate electrophoretic mobility versus maturity relationships were obtained for both intact (supercoiled) and nicked (relaxed) RI. There was considerable overlap between the supercoiled and relaxed RI populations after electrophoretic fractionation. Intact RI could be recovered from preparative agarose gels for further analysis by centrifugation, electron microscopy, re-electrophoresis, or nuclease digestion.     

Analysis of heat-denatured DNA using native agarose gel electrophoresis.

The use of native or neutral gels to resolve denatured DNA affords a rapid and convenient analytical method for assessing the consequences of a number of procedures employed in molecular biology research. We demonstrate that this method can be used to analyze transition melting temperature (Tm) and strand breakage in heat-denatured duplex DNA. This shows that some commonly recommended denaturation procedures can result in significant degradation of DNA and that reannealing or aggregation can occur when samples are concentrated or ionic conditions altered.     

Analysis of the fibrin-polymerizing reaction using sodium dodecylsulfate-agarose gel electrophoresis.

1. A new method of sodium dodecylsulfate gel electrophoresis, sodium dodecyl-sulfate-agarose gel electrophoresis, was developed. The new electrophoresis was shown to have a high and efficient resolving power for fibrin polymers and was also applicable to other proteins. 2. By sodium dodecylsulfate-agarose gel electrophoresis, the fibrin polymerizing reaction with activated fibrin stabilizing factor was analyzed in detail. The cross-linking between the gamma-chains was indicated to occur at an intermolecular level. The solubility of polymerized fibrin was suggested to be related mainly to the formation of the crosslinks between gamma-chains.     

The effect of DNA concentration on mobility in pulsed field gel electrophoresis.

The effect of DNA concentration on pulsed field gel electrophoretic mobility was studied for human genomic DNA prepared in agarose inserts at 8-800 micrograms/ml and digested to completion with Not I. An eighth of each 100 microliter insert was used to produce DNA loads of 0.1 to 10 micrograms per lane. The mobility of single copy restriction fragments, as detected by hybridization, was largely concentration independent when DNA concentrations were 80 micrograms/ml or less. However, at DNA concentrations of 200 micrograms/ml and greater, dramatic effects of DNA concentration are evident. In the worst case, at 800 micrograms/ml, the apparent size of a DNA fragment is almost 2.5 times its true size. At constant DNA concentrations, increasing the DNA mass loads by loading larger insert slices had no further effect on DNA electrophoretic mobility, although the bands were broader for bigger insert slices. Thus, for precise and accurate sizing in pulsed field gel electrophoresis the DNA concentration in agarose inserts should not be greater than 80 micrograms/ml (10(7) diploid human cells/ml agarose insert).     

Discrete mobility of single-stranded DNA in non-denaturing gel electrophoresis

Gel electrophoresis is the standard method to separate, identify and purify nucleic acids. SSCP detects single base changes by altered mobility of single-stranded segments electrophoresed through non-denaturing polyacrylamide gels. Herein, changes in electrophoretic mobilities due to single base substitutions were measured for single-stranded segments of lengths ranging from 333 to 547 nt. A 484 nt segment in exon H of the human factor IX gene was studied most intensively. After SSCP, mobilities were determined by scanning autoradiograms at very high resolution (1200 d.p.i.), which allowed precise measurement of mobilities. When the mobilities of 46 single base substitutions were characterized, the distribution of mutant segments relative to a wild-type control was found to be discrete, i.e. the observed mobility values occurred in distinct ranges. Discrete mobility distributions were seen at different electrophoretic temperatures, buffer concentrations, segment lengths and segment sequences. In addition: (i) single base substitutions caused discontinuous distributions between highly dispersed and sharp bands; (ii) at least one single-stranded segment produced two sharp bands of similar intensity. These observations suggest that: (i) the single base changes in DNA segments in the size range 333–547 nt result in discrete conformational changes; (ii) individual DNA molecules of the same DNA segment can occasionally adopt two or more discrete conformations.     

Characterization of high mobility group protein binding to cisplatin-damaged DNA.

cis-Diamminedichloroplatinum (II) (cisplatin, CDDP) is a widely used chemotherapeutic agent. While many tumors are highly responsive to CDDP, certain tumors are resistant to this drug, limiting its efficacy. The anti-tumor activity of CDDP is believed to result from its coordination bonding to chromosomal DNA. Alterations in tumor cell sensitivity to CDDP may result from the presence or absence of protein(s) which specifically recognize CDDP-damaged DNA. We have developed a damaged-DNA affinity precipitation assay that allows the direct identification of cellular proteins that bind to CDDP-damaged DNA. Using this procedure, we have identified several proteins which specifically bind to CDDP-damaged DNA. Two of these proteins have been identified as high mobility group proteins (HMG) 1 and 2 in the current report, we have characterized the binding of these proteins to CDDP-DNA. The calculated Kd of binding to CDDP-damaged DNA was 3.27 x 10(-10) for HMG1 and 1.87 x 10(-10) for HMG2. Using highly specific chemical modifying reagents, we have determined that Cys residues play an important role in protein binding. We also observed that HMG2 will bind to DNA modified with carboplatin and iproplatin although to a lesser extent than to DNA damaged with CDDP. Thus, our results indicate that HMG 2 binds with high affinity to DNA modified with therapeutically active platinum compounds. In addition, our findings suggest that thiol groups play an essential role in the binding of HMG1 and HMG2 to CDDP-DNA.     

Protein complexes formed during the incision reaction catalyzed by the Escherichia coli UvrABC endonuclease.

An examination has been made into the nature of the nucleoprotein complexes formed during the incision reaction catalyzed by the Escherichia coli UvrABC endonuclease when acting on a pyrimidine dimer-containing fd RF-I DNA species. The complexes of proteins and DNA form in unique stages. The first stage of binding involves an ATP-stimulated interaction of the UvrA protein with duplex DNA containing pyrimidine dimer sites. The UvrB protein significantly stabilizes the UvrA-pyrimidine dimer containing DNA complex which, in turn, provides a foundation for the binding of UvrC to activate the UvrABC endonuclease. The binding of one molecule of UvrC to each UvrAB-damaged DNA complex is needed to catalyze incision in the vicinity of pyrimidine dimer sites. The UvrABC-DNA complex persists after the incision event suggesting that the lack of UvrABC turnover may be linked to other activities in the excision-repair pathway beyond the initial incision reaction.     

Pulsed-field gel electrophoresis of circular DNA.

Mobility of supercoiled (form I) and nicked circular (form II) plasmid DNAs was determined on two major forms of pulsed-field electrophoresis, CHEF and OFAGE. Plasmids with molecular lengths ranging from 2.30 to 17.8 kilobase pairs (kb) were used with Saccharomyces cerevisiae chromosomes as standards. Agarose gel concentrations were varied from 0.3 to 2.0 percent, with higher percentage gels resolving forms I and II of smaller plasmids. The pulsing range of 3.7 to 240 seconds resulted in quite variable Saccharomyces chromosomal mobilities on both 0.5 and 1.0 percent gels, while both form I and II of all plasmid DNAs showed relatively constant mobilities with some increase at the shortest pulse times. Using a 30 second pulse time and gel concentrations of at least 1.0 percent, the usual order of migration of plasmid forms for a 17.8 kb plasmid could be changed. We interpret this result as an increase in the relative mobility of form II in our pulsed-field gel conditions.     

The biased reptation model of DNA gel electrophoresis: mobility vs molecular size and gel concentration

The biased reptation model provides a good framework for interpreting the results of continuous field DNA electrophoresis experiments performed in agarose gels. Here we discuss the main features of the mobility-molecular size and mobility-gel concentration diagrams as obtained from new extensive computer simulations of the model. Our aim is to suggest a global and coherent picture of this widely used yet poorly understood experimental technique, and to point out the areas where a systematic experimental study is still needed.     

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.     

Properties of supercoiled DNA in gel electrophoresis. The V-like dependence of mobility on topological constraint. DNA-matrix interactions

The dependence of the electrophoretic mobility of small DNA rings on topological constraint was investigated in acrylamide or agarose gels as a function of DNA size (from approximately 350 to 1400 base-pairs), gel concentration and nucleotide sequence. Under appropriate adjustment between the size of the DNA and the gel concentration, this dependence was found to be V-shaped in a limited interval around constraint O, the minimum mobility at the apex of the V being obtained for relaxed DNA. Analysis of the DNA size dependence of the V suggests that it is the result of a modulated compaction of the DNA rings by the gel matrix. Compaction appears to be maximum upon relaxation, and to decrease with increase in supercoiling. Consistent with this interpretation, gels were found to oppose structural departures from the B helix, such as Z transition and cruciform extrusion, which tend to relax the DNA molecule and make it more expanded. In contrast, when DNA size or gel concentration are large enough relative to one another, U shapes are observed instead of Vs, as a consequence of an increase in the mobility of the rings closer to relaxation. The relevance of these results to the situation of superhelical DNA in vivo is discussed. Application of the V to the measurement of the DNA helical twist is mentioned.     

Analysis of tubulin isoforms by two-dimensional gel electrophoresis using SDS-polyacrylamide gel electrophoresis in the first dimension.

A two-dimensional electrophoretic system using SDS-polyacrylamide gel electrophoresis (SDS-PAGE) in the first dimension and isoelectric focusing (IEF) in the second dimension was devised. In spite of its simplicity, this method could show a markedly high resolution for tubulin isoforms and moreover could classify them into alpha- or beta-tubulin as a two-dimensional profile. With this method, seven alpha- and four beta-tubulin isoforms could be detected within axoneme from Tetrahymena cilia. Moreover this method could also resolve tubulin isoforms from the rabbit brain. These results indicate that the present two-dimensional gel electrophoresis is a useful tool for the electrophoretic analysis of tubulin isoforms from various sources.     

Analysis of supercoiled DNA by agarose gel electrophoresis using low-conducting sodium threonine medium

We describe a new low-ionic-strength sodium threonine (STh) medium with the advantage of avoiding relative DNA band migration changes following electrophoresis of supercoiled DNA in agarose gel when substituted for the standard conductive medium of TBE (Tris-boric acid-ethylenediaminetetraacetic acid [EDTA]) or TAE (Tris-acetic acid-EDTA) or the low-ionic-strength sodium boric acid medium. Low-ionic-strength STh medium provided better resolution, less heat generation, and prevention of relative migration order changes among linear, covalently closed circular-, and open circular-formed DNA in the range of 2-10 kilobase pairs in 1% agarose gel electrophoresis.