DNA and buffers: the hidden danger of complex formation

The free solution electrophoretic mobility of DNA differs significantly in different buffers, suggesting that DNA-buffer interactions are present in certain buffer systems. Here, capillary and gel electrophoresis data are combined to show that the Tris ions in Tris-acetate-EDTA (TAE) buffers are associated with the DNA helix to approximately the same extent as sodium ions. The borate ions in Tris-borate-EDTA (TBE) buffers interact with DNA to form highly charged DNA-borate complexes, which are stable both in free solution and in polyacrylamide gels. DNA-borate complexes are not observed in agarose gels, because of the competition of the agarose gel fibers for the borate residues. The resulting agarose-borate complexes increase the negative charge of the agarose gel fibers, leading to an increased electroendosmotic flow of the solvent in agarose-TBE gels. The combined results indicate that the buffers in which DNA is studied cannot automatically be assumed to be innocuous.     

Curved DNA molecules migrate anomalously slowly in free solution

The electrophoretic mobility of a curved DNA restriction fragment taken from the VP1 gene in the SV40 minichromosome has been measured in polyacrylamide gels and free solution, using capillary electrophoresis. The 199 bp restriction fragment has an apparent bend angle of 46 ± 2° located at SV40 sequence position 1922 ± 2 bp [Lu Y.J., Weers B.D. and Stellwagen N. C. (2005) Biophys. J., 88, 1191–1206]. The ‘curvature module’ surrounding the apparent bend center contains five unevenly spaced A- and T-tracts, which are responsible for the observed curvature. The parent 199 bp fragment and sequence mutants containing at least one A-tract in the curvature module migrate anomalously slowly in free solution, as well as in polyacrylamide gels. Hence, the anomalously slow mobilities observed for curved DNA molecules in polyacrylamide gels are due in part to their anomalously slow mobilities in free solution. Analysis of the gel and free solution mobility decrements indicates that each A- or T-tract contributes independently, but not equally, to the curvature of the 199 bp fragment and its A-tract mutants. The relative contribution of each A- or T-tract to the observed curvature depends on its spacing with respect to the first A-tract in the curvature module.     

Silver and Cyanine Staining of Oligonucleotides in Polyacrylamide Gel

To explore why some oligonucleotides in denaturing polyacrylamide gel could not be silver-stained, 134 different oligonucleotides were analyzed using denaturing polyacrylamide gel electrophoresis stained with silver and asymmetric cyanine. As a result, we found that the sensitivity of oligos (dA), (dC), (dG) and (dT) to silver staining could be ranged as (dA) > (dG) > (dC) > (dT) from high to low. It was unexpected that oligo (dT) was hard to be silver-stained. Moreover, the silver staining of an oligonucleotide containing base T could be partially or completely inhibited by base T. The inhibition of silver staining by base T was a competitive inhibition which could be affected by the amounts of the argyrophil nucleobase and base T, the cis-distance between the argyrophil nucleobase and base T, and the gel concentration. The changes of the intensity of an oligonucleotide band caused by the changes of DNA base composition were diverse and interesting. The intensity of some oligonucleotide bands would significantly change when the changes of DNA base composition accumulated to a certain extent (usually ≥ 4 nt). The sensitivity of cyanine staining of ≤ 11-nt long oligonucleotides could be enhanced about 250-fold by fixing the gels with methanol fixing solution.     

Characterization of DNA metabolizing enzymes in situ following polyacrylamide gel electrophoresis

We have detected the in situ activities of DNA glycosylase, endonuclease, exonuclease, DNA polymerase, and DNA ligase using a novel polyacrylamide activity gel electrophoresis procedure. DNA metabolizing enzymes were resolved through either native or SDS-polyacrylamide gels containing defined 32P-labeled oligonucleotides annealed to M13 DNA. After electrophoresis, these enzymes catalyzed in situ reactions and their [32P]DNA products were resolved from the gel by a second dimension of electrophoresis through a denaturing DNA sequencing gel. Detection of modified (degraded or elongated) oligonucleotide chains was used to locate various enzyme activities. The catalytic and physical properties of Novikoff hepatoma DNA polymerase beta were found to be similar under both in vitro and in situ conditions. With 3'-terminally matched and mismatched [32P]DNA substrates in the same activity gel, DNA polymerase and/or 3' to 5' exonuclease activities of Escherichia coli DNA polymerase I (large fragment), DNA polymerase III (holoenzyme), and exonuclease III were detected and characterized. In addition, use of matched and mismatched DNA primers permitted the uncoupling of mismatch excision and chain extension steps. Activities first detected in nondenaturing activity gels as either multifunctional or multimeric enzymes were also identified in denaturing activity gels, and assignment of activities to specific polypeptides suggested subunit composition. Furthermore, DNA substrates cast within polyacrylamide gels were successfully modified by the exogenous enzymes polynucleotide kinase and alkaline phosphatase before and after in situ detection of E. coli DNA ligase activity, respectively. Several restriction endonucleases and the tripeptide (Lys-Trp-Lys), which acts as an apurinic/apyrimidinic endonuclease, were able to diffuse into gels and modify DNA. This ability to create intermediate substrates within activity gels could prove extremely useful in delineating the steps of DNA replication and repair pathways.     

Affinity electrophoresis: New simple and general methods of preparation of affinity gels

Two simple and generally applicable methods of preparation of affinity gels for affinity electrophoresis in agarose and polyacrylamide gels are described. In the first method, amino ligands are coupled to periodate-oxidized agarose gel beads (Sepharose 4B), and homogeneous affinity gels are obtained after mixing the melted substituted beads with either melted agarose solution or with the polymerization mixture used for the preparation of polyacrylamide gels. This type of affinity gel was used for affinity electrophoresis of lectins (immobilized p-aminophenyl glycosides), ribonuclease (immobilized uridine 3′,5′-diphosphate 5′-p-aminophenyl ester), trypsin (immobilized p-aminobenzamidine), and double-stranded phage DNA fragments (immobilized acriflavine). Alternatively, heterogeneous affinity gels are prepared from the suspension of ligand-substituted agarose, dextran, or polyacrylamide gel beads in the polymerization solution normally used for preparation of polyacrylamide electrophoretic gels. This technique was used for affinity electrophoresis of lectins, ribonuclease, and trypsin on affinity gels containing appropriate ligands coupled to the gel beads “activated” by various methods. Applicability of affinity gels prepared by the two methods described above for affinity isoelectric focusing is demonstrated.     

Cellulose and Callose Biosynthesis in Higher Plants (I. Solubilization and Separation of (1->3)- and (1->4)-[beta]-Glucan Synthase Activities from Mung Bean)

(1->3)- and (1->4)-[beta]-glucan synthase activities from higher plants have been physically separated by gel electrophoresis in nondenaturing conditions. The two glucan synthases show different mobilities in native polyacrylamide gels. Further separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a different polypeptide composition in these synthases. Three polypeptides (64, 54, and 32 kD) seem to be common to both synthase activities, whereas two polypeptides (78 and 38 kD) are associated only with callose synthase activity. Twelve polypeptides (170, 136, 108, 96, 83, 72, 66, 60, 52, 48, 42, and 34 kD) appear to be specifically associated with cellulose synthase activity. The successful separation of (1->3)- and (1->-4)-[beta]-glucan synthase activities was based on the manipulation of digitonin concentrations used in the solubilization of membrane proteins. At low dipitomin concentrations (0.05 and 0.1%), the ratio of the cellulose to callose synthase activity was higher. At higher digitonin (0.5-1%) concentrations, the ratio of the callose to cellulose synthase activity was higher. Rosette-like particles with attached product were observed in samples taken from the top of the stacking gel, where only cellulose was synthesized. Smaller (nonrosette) particles were found in the running gel, where only callose was synthesized. These findings suggest that a higher level of subunit organization is required for in vitro cellulose synthesis in comparison with callose assembly.     

Molecular weights of estrogen and androgen binding proteins in the liver of Xenopus laevis.

[3-H]Estradiol-17beta and [3-H]dihydrotestosterone binding proteins in the cytosol fraction of liver from both male and female Xenopus laevis were characterized by electrophoresis on polyacrylamide gels. These binding proteins, which were indistinguishable based upon their mobilities on gels of different acrylamide concentrations, migrated as single components with a molecular weight of 2.0 x 10-4. Separation of native or sodium dodecyl sulfate denatured specific estrogen-binding components on dodecyl sulfate free acrylamide gels gave similar results, i.e., a single species of molecular weight 2.0-2.5 x 10-4. The same molecular weight also was obtained when cytosol was prepared in the presence of either diisopropyl fluorophosphate or phenylmethanesulfonyl fluoride, protease inhibitors. Evidence that the liver components binding either [3-H]estradiol-17-beta or [3-H]dihydrotestosterone were not plasma contaminants was provided by the observation that the plasma sex-steroid binding globulin of Xenopus had a different mobility when separated by polyacrylamide gel electrophoresis.     

Polyacrylamide gel as a medium for DNA dissociation and reassociation

Several properties of thermal denaturation and renaturation of DNA in polyacrylamide gels were investigated: (1) Following electrophoresis the DNA band was scanned and shown to increase in absorbance with increasing temperature. The increase was proportioned to DNA concentration across the peak. (2) The dependence of theT _m on salt concentration over a hundred fold range was similar to that found for DNA in free solution. (3) Denaturation of several DNA samples ranging in G+C content from 26 to 71% was compared in gels and free solution. The relationship betweenT _m and % G+C was virtually identical for both sets of DNAs. (4) The kinetics of DNA renaturation in the gel was followed. Reassociation of bacteriophageT ₄ DNA was 2nd order and proceeded more rapidly in polyacrylamide gels than in free solution.     

Intrinsic curvature in the VP1 gene of SV40: comparison of solution and gel results

DNA restriction fragments that are stably curved are usually identified by polyacrylamide gel electrophoresis because curved fragments migrate more slowly than normal fragments containing the same number of basepairs. In free solution, curved DNA molecules can be identified by transient electric birefringence (TEB) because they exhibit rotational relaxation times that are faster than those of normal fragments of the same size. In this article, the results observed in free solution and in polyacrylamide gels are compared for a highly curved 199-basepair (bp) restriction fragment taken from the VP1 gene in Simian Virus 40 (SV40) and various sequence mutants and insertion derivatives. The TEB method of overlapping fragments was used to show that the 199-bp fragment has an apparent bend angle of 46 +/- 2 degrees centered at sequence position 1922 +/- 2 bp. Four unphased A- and T-tracts and a mixed A3T4-tract occur within a span of approximately 60 bp surrounding the apparent bend center; for brevity, this 60-bp sequence element is called a curvature module. Modifying any of the A- or T-tracts in the curvature module by site-directed mutagenesis decreases the curvature of the fragment; replacing all five A- and T-tracts by random-sequence DNA causes the 199-bp mutant to adopt a normal conformation, with normal electrophoretic mobilities and birefringence relaxation times. Hence, stable curvature in this region of the VP1 gene is due to the five unphased A- and T- tracts surrounding the apparent bend center. Discordant solution and gel results are observed when long inverted repeats are inserted within the curvature module. These insertion derivatives migrate anomalously slowly in polyacrylamide gels but have normal, highly flexible conformations in free solution. Discordant solution and gel results are not observed if the insert does not contain a long inverted repeat or if the long inverted repeat is added to the 199-bp fragment outside the curvature module. The results suggest that long inverted repeats can form hairpins or cruciforms when they are located within a region of the helix backbone that is intrinsically curved, leading to large mobility anomalies in polyacrylamide gels. Hairpin/cruciform formation is not observed in free solution, presumably because of rapid conformational exchange. Hence, DNA restriction fragments that migrate anomalously slowly in polyacrylamide gels are not necessarily stably curved in free solution.     

Thermal denaturation of nucleic acids in polyacrylamide gels

A system is described for measuring thermal denaturation of nucleic acid fractions directly in polyacrylamide gels. Total nucleic acids were fractionated by disc gel electrophoresis. The buffer within the gel was then exchanged for one commonly used in denaturation studies. Thermal denaturation profiles of DNA and ribosomal RNA in the gel were determined using a specially constructed Gel Carriage to position the appropriate fraction during spectrophotometric measurements. These profiles were compared with denaturation patterns obtained by classical methods in free solution; the two methods yielded similar patterns.Thermal denaturation profiles were also obtained for chloroplast light ribosomal RNA resolved by gel electrophoresis of total plant nucleic acids. Thus, denaturation patterns of individual, minor components present in complex nucleic acid mixtures can be directly measured in gels.     

Preferential binding of Escherichia coli RecF protein to gapped DNA in the presence of adenosine (gamma-thio) triphosphate.

Escherichia coli RecF protein binds, but does not hydrolyze, ATP. To determine the role that ATP binding to RecF plays in RecF protein-mediated DNA binding, we have determined the interaction between RecF protein and single-stranded (ss)DNA, double-stranded (ds)DNA, and dsDNA containing ssDNA regions (gapped [g]DNA) either alone or in various combinations both in the presence and in the absence of adenosine (gamma-thio) triphosphate, gamma-S-ATP, a nonhydrolyzable ATP analog. Protein-DNA complexes were analyzed by electrophoresis on agarose gels and visualized by autoradiography. The type of protein-DNA complexes formed in the presence of gamma-S-ATP was different with each of the DNA substrates and from those formed in the absence of gamma-S-ATP. Competition experiments with various combinations of DNA substrates indicated that RecF protein preferentially bound gDNA in the presence of gamma-S-ATP, and the order of preference of binding was gDNA > dsDNA > ssDNA. Since gDNA has both ds- and ssDNA components, we suggest that the role for ATP in RecF protein-DNA interactions in vivo is to confer specificity of binding to dsDNA-ssDNA junctions, which is necessary for catalyzing DNA repair and recombination.     

Thermal Stability of Immobilized Glucoamylase Entrapped in Polyacrylamide Gels and Bound to SP-Sephadex C–50

Glucoamylase[α-1,4: 1,6-glucan-4: 6-glucohydroease, EC 3.2.1.3] from Rhizopus niveus was entrapped in polyacrylamide gels and adsorbed onto SP-Sephadex C–50 to elucidate the thermostability mechanism of immobilized enzymes. The thermal stability of immobilized glucoamylase entrapped in polyacrylamide gels was enhanced slightly compared with glucoamylase in free solution, and was independent of the acrylamide monomer concentration and N, N′-methylene-bis (acrylamide) content. To explain this phenomenon, the cellular structure of polyacrylamide gel was taken into consideration in addition to interactions between glucoamylase and gel, and a decrease in dielectric constant in the gel [S. Moriyama et al., Agric. Biol. Chem., 41, 1985 (1977)¹⁾]. On the other hand, immobilized glucoamylase bound to SP-Sephadex by ionic interaction showed lower stability than free glucoamylase, and much greater stability than glucoamylase in the presence of dextran sulfate, a constituent of SP-Sephadex. Thermal stabilities for the free and immobilized enzymes were also compared at the pH not in the bulk solution, but in the SP-Sephadex.     

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.     

A technique of low-pH gel electrophoresis of chromosomal proteins which does not require preliminary removal of DNA.

Fractionation of chromosomal proteins, in particular, of histones, by acetic acid-urea polyacrylamide gel electrophoresis usually requires preliminary removal of DNA from deoxyribonucleoprotein samples to obtain good separation of proteins. We have found that this difficulty can be overcome by addition of cetyltrimethylammonium bromide (CTAB) to the gel and electrode buffers. Since CTAB can readily diffuse into polyacrylamide gels two-dimensional fractionation becomes possible; that is, deoxyribonucleoprotein particles are fractionated in the first dimension followed by immersion of a gel in a CTAB solution and then low-pH gel electrophoresis of proteins in the second dimension.     

Differences in pattern of a DNA protein complex isolated from vegetative cells and spores of Bacillus subtilis.

Summary A DNA protein complex has been isolated from vegetative cells and spores of Bacillus subtilis. Properties of the DNA protein complex prepared from vegetative cells were studied and SDS gel electrophoresis was employed to compare the different DNase-untreated and-treated DNA protein complexes. It is concluded that proteins are associated with the DNA and differences in protein pattern in polyacrylamide gels indicates the involvement of DNA-binding proteins in the regulation of spore formation.     

Oligo(dT) is not a correct native PAGE marker for single-stranded DNA

Polyacrylamide gel electrophoresis is a widely used method to study short DNA fragments in solution. It is, however, a relative method requiring length markers to assess mobility, shape, flexibility, and molecularity of the DNA structures of interest. In recent literature we have encountered the use of oligo(dT) fragments as the native PAGE length markers. We show here that this practice is inadequate because oligo(dT) migration is strongly retarded in native polyacrylamide gels. This conclusion is qualitatively true irrespective of the conditions of electrophoresis, oligo(dT) length, and gel concentration. Depending on their length, oligo(dT) fragments migrate 2--4 times slower than that would correspond to their nucleotide number. This leads to erroneous conclusions, e.g., determination of the number of associated molecules in guanine quadruplexes or other DNA complexes.     

Sequence specificity of the non-natural pyrido[2,3-d]pyrimidine nucleoside in triple helix formation.

The non-natural pyrido[2,3-d]pyrimidine nucleoside F, which pairs preferentially with guanine (G) and adenine (A) within double-helical DNA, recognizes with high selectivity AT base pairs within triple-helical complexes. These observations suggest that F may exist in different tautomeric forms within double-helical and triple-helical complexes. Analysis of the base stacking properties of this extended ring system using two oligodeoxyribonucleotides containing terminal thymines and/or pyrido[2,3-d]pyrimidines bound to adjacent sites showed a decrease in free energy of binding in a triple-helical complex in the order (5'-3') TT > FT > TF > FF.     

Separation of the DNA molecules beyond conventional size limits by gel electrophoresis with sodium dodecyl sulfate.

Electrophoretic mobility of DNA through polyacrylamide as well as agarose gels is greatly increased by sodium dodecyl sulfate (SDS). DNA molecules well beyond the conventionally separable size limits are separated readily and rapidly by gel electrophoresis with SDS in a conventional static electric field. Furthermore in optimal concentration gels DNA molecules of similar molecular sizes are separated better from one another in the presence of SDS than without it. Evidence is presented that SDS may act at least in part by altering conformation of DNA. This simple and readily available means for high resolution separation of hitherto impossible sizes of DNA molecules in polyacrylamide and agarose gels in an ordinary static electric field should find general use in molecular genetic analyses. Structural analyses of DNA-protein complexes are also facilitated by virtue of the simultaneous separation of the DNA and protein components on the same gel lane.