Capillary electrophoresis as a method to study DNA reassociation

To develop analytical methodology to assess the genetic complexity of a DNA sample, capillary electrophoresis with laser-induced fluorescence detection is used to monitor the annealing process of DNA samples. Coated columns are filled with an entangled polymer solution shown to optimally separate DNA through size-selective capillary electrophoresis. DNA samples are denatured by heating in a boiling water bath for approximately 10 min and then cooled to approximately 25 degrees C below the melting point of the DNA sample to initiate the reassociation process. The DNA is detected by means of the laser-induced fluorescence of intercalated ethidium bromide, which produces a substantially greater signal for double- versus single-stranded DNA. The rate of reassociation is dependent upon the rate at which complimentary strands of DNA encounter each other and the degree of repeating base sequences in the sample (hence, the diversity of the DNA). Experimental parameters also influence the reassociation rate. The effects of salt concentration and incubation temperature are presented. Traditional plots of C(o)t (C(o) = DNA concentration and t = reassociation time) versus % recovery of double-stranded DNA signal are generated for PhiX 174 Hae III digest and 50 bp stepladder DNA, individually and combined, to calculate the reassociation rate constants for these samples. Because reassociation of individual fragments is observed by the CE-LIF method, more information about the samples is available than with less specific and time-consuming traditional methods of investigating DNA reassociation.     

Capillary electrophoresis as a verification tool for immunochemical drug screening

BACKGROUnd: The aim of this work was to develop a simple capillary electrophoretic method as the verification and confirmation tool in the screening analysis for amphetamines, opiates, benzodiazepines and cocaine and their metabolites for toxicological applications. METHODS: 50 mM phosphate Tris pH 2.0 with 30% (v/v) of methanol was used as a background electrolyte that enabled fast separation of drugs and their metabolites in saliva and urine. Verification of the data from the electrophoretic method was done by High Performance Thin Layer Chromatography (HPTLC) and the immunochemical screening test QuikScreen. RESULTS: The experimental conditions of the Capillary Electrophoresis (CE) were partially optimized (mainly the influence of concentration and types of additives, e.g. cyclodextrines, organic solvents) and validated; the method was used for analysing samples from drug abusers. CONCLUSIONS: The non-instrumental, immunoassay tests could only confirm qualitative addictions and are mainly employed when the emergency detection of drugs is needed. For quantitative analysis and verification of obtained results the confirmation step is strongly recommended. The simple screening capillary zone electrophoresis method allows recognition of the most abused drugs. The agreement of the results from CE, HPTLC and QuikScreen test was more than 95%.     

Capillary affinity gel electrophoresis: new technique for specific recognition of DNA sequence and the mutation detection on DNA

The present state of studies on capillary affinity gel electrophoresis, which is a new technique for the specific recognition of a target DNA sequence, is reviewed. This article includes the principle, theory, methods, and applications of this technology. The great potential of capillary affinity gel electrophoresis for the sequence-specific recognition of DNA and the detection of mutations in specific genes is illustrated.     

A program for selecting DNA fragments to detect mutations by denaturing gel electrophoresis methods.

A computer program was developed to automate the selection of DNA fragments for detecting mutations within a long DNA sequence by denaturing gel electrophoresis methods. The program, MELTSCAN, scans through a user specified DNA sequence calculating the melting behavior of overlapping DNA fragments covering the sequence. Melting characteristics of the fragments are analyzed to determine the best fragment for detecting mutations at each base pair position in the sequence. The calculation also determines the optimal fragment for detecting mutations within a user specified mutational hot spot region. The program is built around the statistical mechanical model of the DNA melting transition. The optimal fragment for a given position is selected using the criteria that its melting curve has at least two steps, the base pair position is in the fragment's lowest melting domain, and the melting domain has the smallest number of base pairs among fragments that meet the first two criteria. The program predicted fragments for detecting mutations in the cDNA and genomic DNA of the human p53 gene.     

Fast gel electrophoresis to analyze DNA-protein interactions

A rapid method for electrophoresis of DNA-protein complexes is described. Popular "gel-shift" assays are performed using Pharmacia PhastSystem with its convenience of pre-cast gels and buffer strips and microprocessor-controlled high-resolution separation. Using this system, the products of a DNA binding reaction (DNA-protein complexes) can be separated from "free" DNA in less than one hour. DNA fragments as well as oligonucleotides have been used as targets with partially purified extracts containing sequence-specific DNA binding proteins. We present here a comparison of results of gel-shift assays obtained by conventional techniques and by our rapid "PhastShift" method which reduces the time, effort and technical expertise necessary to obtain reproducible results.     

Detection of specific sequences among DNA fragments separated by gel electrophoresis.

Ribosomal RNA and precursor ribosomal RNA from at least one representative of each vertebrate class have been analyzed by electron microscopic secondary structure mapping. Reproducible patterns of hairpin loops were found in both 28 S ribosomal and precursor ribosomal RNA, whereas almost all the 18 S ribosomal RNA molecules lack secondary structure under the spreading conditions used. The precursor ribosomal RNA of all species analyzed have a common design. The 28 S ribosomal RNA is located at or near the presumed 5′-end and is separated from the 18 S ribosomal RNA region by the internal spacer region. In addition there is an external spacer region at the 3′-end of all precursor ribosomal RNA molecules. Changes in the length of these spacer regions are mainly responsible for the increase in size of the precursor ribosomal RNA during vertebrate evolution. In cold blooded vertebrates the precursor contains two short spacer regions; in birds the precursor bears a long internal and a short external spacer region, and in mammals it has two long spacer regions. The molecular weights, as determined from the electron micrographs, are 2·6 to 2·8 × 10⁶ for the precursor ribosomal RNA of cold blooded vertebrates, 3·7 to 3·9 × 10⁶ for the precursor of birds, and 4·2 to 4·7 × 10⁶ for the mammalian precursor. Ribosomal RNA and precursor ribosomal RNA of mammals have a higher proportion of secondary structure loops when compared to lower vertebrates. This observation was confirmed by digesting ribosomal RNAs and precursor ribosomal RNAs with single-strandspecific S₁ nuclease in aqueous solution. Analysis of the double-stranded, S₁-resistant fragments indicates that there is a direct relationship between the hairpin loops seen in the electron microscope and secondary structure in aqueous solution.     

Detecting base pair substitutions in DNA fragments by temperature-gradient gel electrophoresis.

A vertical gel electrophoresis apparatus is described which can distinguish DNA fragments differing by single base pair substitutions. The system employs a homogenous polyacrylamide gel containing urea-formamide and a temperature gradient which runs either perpendicular or parallel to the direction of electrophoresis. The temperature-gradient system simplifies several features of the denaturant-gradient system (1) and is relatively inexpensive to construct. Eight homologous 373 bp DNAs differing by one, two, or nine base pair substitutions were examined. DNA electrophoretic mobility changed abruptly with the temperature induced unwinding of DNA domains. GC to AT substitutions at different locations within the first melting domain, as well as an AT to TA transversion were separated with temperature gradients parallel to the electrophoretic direction. The relative stabilities of the DNAs observed in the gels were compared to predictions of DNA melting theory. General agreement was observed however complete correspondence was not obtained.     

Tandem repeats finder: a program to analyze DNA sequences.

A tandem repeat in DNA is two or more contiguous, approximate copies of a pattern of nucleotides. Tandem repeats have been shown to cause human disease, may play a variety of regulatory and evolutionary roles and are important laboratory and analytic tools. Extensive knowledge about pattern size, copy number, mutational history, etc. for tandem repeats has been limited by the inability to easily detect them in genomic sequence data. In this paper, we present a new algorithm for finding tandem repeats which works without the need to specify either the pattern or pattern size. We model tandem repeats by percent identity and frequency of indels between adjacent pattern copies and use statistically based recognition criteria. We demonstrate the algorithm's speed and its ability to detect tandem repeats that have undergone extensive mutational change by analyzing four sequences: the human frataxin gene, the human beta T cellreceptor locus sequence and two yeast chromosomes. These sequences range in size from 3 kb up to 700 kb. A World Wide Web server interface atc3.biomath.mssm.edu/trf.html has been established for automated use of the program.     

Multi-priming sequencing: a DNA sequencing method involving restriction enzyme-digested DNA fragments as primers.

An improved strategy for fluorescence-labeled dideoxy chain termination sequencing involving restriction enzyme-digested DNA fragments as primers, which are prepared from the DNA to be sequenced, is described. By using modified nucleoside triphosphates for strand protection in chain termination reactions, newly synthesized chains were detached from a primer at the regenerated recognition site by means of suitable restriction enzyme digestion. The digests could be analyzed with commercial automated DNA sequencers. Thus, by using restriction DNA fragments (double-stranded) as primers, sequence information was obtained from both "minus" and "plus" single-stranded DNA templates without subcloning. Nor is the synthesis of oligonucleotide primers needed. This method, named "Multi-Priming Sequencing," was proven to be time-saving, economical, and effective compared to conventional methods.     

Capillary electrophoresis of DNA in uncrosslinked polymer solutions: evidence for a new mechanism of DNA separation

The electrophoretic separation of DNA molecules is usually performed in thin slabs of agarose or polyacrylamide gel. However, DNA separations can be achieved more rapidly and efficiently within a microbore fused silica capillary filled with an uncrosslinked polymer solution. An early assumption was that the mechanism of DNA separation in polymer solution(SINGLEBOND)capillary electrophoresis (PS(SINGLEBOND)CE) is the same as that postulated to occur in slab gel electrophoresis, i.e., that entangled polymer chains form a network of "pores" through which the DNA migrates. However, we have demonstrated that large DNA restriction fragments (2.0(SINGLEBOND)23.1 kbp) can be separated by CE in extremely dilute polymer solutions, which contain as little as 6 parts per million [0.0006% (w/w)] of uncrosslinked hydroxyethyl cellulose (HEC) polymers. In such extremely dilute HEC solutions, far below the measured polymer entanglement threshold concentration, pore-based models of DNA electrophoresis do not apply. We propose a transient entanglement coupling mechanism for the electrophoretic separation of DNA in uncrosslinked polymer solutions, which is based on physical polymer/DNA interactions. (c) 1996 John Wiley & Sons, Inc.     

Capillary electrophoresis is a sensitive monitor of the hairpin-random coil transition in DNA oligomers

Capillary electrophoresis (CE) has been used to characterize the hairpin-random coil transition of four octamers in the GCxxxxGC minihairpin family, where xxxx is GAAA, TTTC, TTTT, or AAAA. The transition can be monitored by CE because differences in the frictional coefficients of the hairpin and coil forms of each octamer lead to a difference of approximately 9% in the free solution mobilities of the two conformations. The GAAA octamer is unusually stable, with a melting temperature of 65 degrees C. The TTTT octamer forms a minihairpin with a melting temperature of 29 degrees C, the TTTC octamer has a melting temperature of 16 degrees C, and the AAAA octamer has a melting temperature below 0 degrees C. The thermal transitions of the TTTT, TTTC, and AAAA octamers are well fitted by a structure prediction algorithm; however, the GAAA minihairpin is considerably more stable than predicted. The melting temperature of the GAAA minihairpin is reduced to 47 degrees C in aqueous buffers containing 7.2M urea and to 33 degrees C in buffers containing 7.2M urea plus 40% (v/v) formamide. The combined results indicate that CE is a sensitive technique for monitoring conformational transitions in small DNA molecules.     

Detection of a single base exchange in PCR-amplified DNA fragments using agarose gel electrophoresis containing bisbenzimide-PEG.

Using PCR fragments of known sequences derived from isolates of two related fungal species, simple submarine electrophoresis in agarose gels containing a bisbenzimide-PEG conjugate (H.A.-Yellow) has been shown to be capable of distinguishing DNA fragments 567 bp long which differ by as little as a single base change. However, only changes affecting bisbenzimide binding sites (which consist of at least four consecutive A/T bases) alter mobility; other changes are ineffective. A second ligand (H.A.-Red) with high G/C specificity is suggested which may be as effective in detecting other sequence changes.     

Pulsed field gel electrophoresis techniques for separating 1- to 50-kilobase DNA fragments

Conventional agarose gel electrophoresis separates DNA using a static electric field. The maximum size limit for separation of DNA by this method is about 20 kilobase pairs (kb). A number of new electrophoretic techniques which employ periodic reorientation of electric fields permit separation of DNA well beyond this size limit. We sought to determine whether the use of very fast (millisecond) field switching could improve separation of DNA in the size range of 1 to 50 kb. Additionally, we have compared the resolution obtained with each of the different field switching regimens for DNA in this size range. Switching intervals of from 0.2 to 900 ms were used with unidirectional pulsing of a single electric field, with pulsed field gels, and with field inversion gel electrophoresis. Plotting the mobility of DNA as a function of size demonstrates that under the conditions used, each of these techniques offers comparable resolution. We also have examined the separation obtained when field inversion gels are run with forward and reverse fields of equal voltage and different durations, versus using fields of equal duration and different voltages. Field inversion which uses forward and reverse fields of different voltages yields resolution which is superior to the other methods examined.