Use of double gradient denaturing gradient gel electrophoresis to detect (AT)n polymorphisms in the UDP-glucuronosyltransferase 1 gene promoter associated with Gilbert's syndrome.

Gilbert's syndrome, due to reduced hepatic bilirubin glucuronidation is associated with the presence of two extra nucleotides (TA) in the promoter region of the UDP-glucuronosyltransferase 1 (UGT1A1) gene. A rapid method was developed to detect this genetic polymorphism, using double gradient denaturing gradient gel electrophoresis (DG-DGGE). The promoter region of the UGT1A1 gene was amplified with a 40-mer GC-clamp attached to the 5'-end of the reverse primer. The polymerase chain reaction (PCR) product was then separated by DG-DGGE using denaturant concentrations of 15-25% and polyacrylamide concentrations of 6-12%. The (TA)6/(TA)6 homozygotes were clearly distinguished from both (TA)7/(TA)7 homozygotes and (TA)6/(TA)7 heterozygotes. The (TA)7 allele frequency was consistent with that previously reported and elevated bilirubin levels correlated with the presence of the (TA)7 allele. The DG-DGGE method described will make detection for this polymorphism fast, simple, nonradioactive and suitable for a clinical routine diagnostic laboratory, helping to establish the role of this polymorphism in individuals with jaundice due to multiple causes.     

Microbial diversity in biodeteriorated monuments as studied by denaturing gradient gel electrophoresis

Studies of the microorganisms living on cultural assets and their potential damaging effects begin with an understanding of the microbial diversity present in such samples. Recently, molecular techniques have started to attract considerable interest since they do not require the culture of microorganisms in order to detect their presence. The basic protocol followed during microbial diversity analysis on cultural heritage assets utilizes electrophoretic techniques for separating highly homologous sequences. At present, Denaturing Gradient Gel Electrophoresis (DGGE) is the most frequently reported technique for separating DNA fragments during microbial diversity studies of art objects. In this report, we describe DGGE profiling techniques, show the most common applications, and present some examples of their use in microbial diversity studies on cultural heritage.     

Scanning the beta-globin gene for mutations in large populations by denaturing capillary and gel electrophoresis

Separation of mutant from nonmutant DNA sequences of 100 bp may be accomplished by using defined denaturing conditions of chemical denaturant and/or elevated temperature during electrophoresis on either polyacrylamide slab gels (denaturing gradient gel electrophoresis, DGGE) or capillary gels (constant denaturant capillary electrophoresis, CDCE). In analysis of mutant directly from a polymerase chain reaction (PCR) product mixture, both have detection sensitivities of approximately 1%. CDCE that facilitates an intermediate mutant enrichment step permits detection of mutants at fractions as low as 2 x 10(-6). Here we report the successful application of both approaches to scan for mutations of the human beta-globin gene (HBB) in two human population samples of approximately 5000 persons in the HBB. Using DGGE, the coding region and flanking intronic splice sites of HBB were scanned in a population of 4949 Han Chinese individuals in pool sizes of 48 individual DNA samples. Four point mutations ranging in mutant frequency from 0.5 to 0.0002 were identified. Using CDCE with a mutant enrichment step, these same sequences were scanned in a population of 5028, predominantly African-American juveniles (<9 years) as a single pooled DNA sample. Three point mutations were identified ranging in mutant frequency from 0.13 to 0.0005. This study shows that both the DGGE/small pool and the CDCE/large pool approaches offer the means to define the fine structure map of genetic variation in large population samples, and with appropriately engineered facilities to provide high throughput, should be useful in pangenomic scans to discover genes carrying casual mutations for common diseases.     

Use of voltage gradient gel electrophoresis in apoptotic DNA analysis

In this paper the use of voltage gradient gel electrophoresis (VGGE) in the electrophoretic analysis of apoptotic DNAs is described. The peculiarity of VGGE fractionation in enhancing DNA bands in the gel by reducing their thickness was used to obtain a rapid, more selective and higher-quality electrophoretic fractionation of apoptotic DNA with respect to conventional electrophoresis. The use of VGGE fractionations also allowed a reduced amount of DNA to be used to detect a characteristic apoptotic DNA ladder pattern, in a lower agarose gel concentration, with respect to conventional electrophoretic fractionation     

Polyacrylamide gel electrophoresis followed by sodium dodecyl sulfate gradient polyacrylamide gel electrophoresis for the study of the dimer to monomer transition of human transthyretin

Familial amyloidotic polyneuropathy (FAP) is caused by mutations which destabilize transthyretin (TTR) and facilitate the aggregation into extracellular amyloid fibrils preferentially in peripheral nerve and heart tissues. Therapeutic and preventive trials for FAP at the plasma TTR level require a careful study of the destabilization of TTR under variable conditions. We have developed a simple double one-dimensional (D1-D) electrophoretic procedure with polyacrylamide gel electrophoresis (PAGE) followed by sodium dodecylsulfate (SDS) gradient PAGE to study the dimer to monomer transition. TTR is first isolated by PAGE from other plasma proteins. The gel strip containing the TTR fraction is incubated in 2% SDS under varying conditions of temperature, buffer composition, pH, and additives like urea and/or a sulfhydryl-reactive agent, followed by SDS-gradient PAGE for the separation of TTR dimers and monomers. We demonstrate that an unidirectional dimer to monomer transition of normal TTR is achieved at 70-80 degrees C in neutral to mild alkaline buffers or at 37 degrees C and slightly acidic pH (6-7). Addition of urea favors the transition into monomers. Amyloidogenic mutations like amyloidogenic TTR (ATTR)-V30M or ATTR-I107V favor the transition into monomers in buffer systems close to the physiological pH of human plasma. We conclude that this finding has to be considered by any hypothesis on ATTR-derived amyloidogenesis.     

Detection of mitochondrial DNA mutations using temporal temperature gradient gel electrophoresis

Mitochondrial disorders are a group of clinically and genetically heterogeneous diseases. Common recurrent mitochondrial DNA (mtDNA) point mutations account for the molecular defects of a small proportion of patients. In order to identify mtDNA mutations, comprehensive mutational analysis of the entire mitochondrial genome is necessary. We developed the temporal temperature gradient gel electrophoresis (TTGE) method to screen for mutations in mtDNA. The entire mitochondrial genome was amplified using 32 pairs of overlapping primers followed by TTGE analysis of the DNA fragments. TTGE method was first validated on 200 DNA fragments containing known mutations or polymorphisms. On TTGE, homoplasmic nucleotide substitutions show a single band shift and heteroplasmic mutations show multiple banding patterns. The known mutations or polymorphisms were correctly identified. TTGE was then used to screen for unknown mutations in the mitochondrial genome. DNA banding patterns, deviated from wild-type, suggestive of either homoplasmic or heteroplasmic mutations, were followed by direct DNA sequencing to identify the mutations. Numerous mutations and polymorphisms were detected. The results demonstrated that TTGE detects and distinguishes heteroplasmic mutations from homoplasmic polymorphisms. It also detects heteroplasmic changes in the background of a homoplasmic polymorphism. Overall, TTGE was proven to be a simple, rapid, sensitive, and effective mutation detection method.     

Analysis of DNA polymorphisms on the human Y-chromosome by microchip electrophoresis

Validation of microchip electrophoresis in DNA analysis has been carried out using an Agilent 2100 Bioanalyzer. With a DNA 500 Assay Kit, the reproducibility and accuracy of fragment sizing of a 10 bp DNA ladder have been shown to be satisfactory with the relative standard deviation and the relative error mostly below 1.0 and 5.0% (n = 12), respectively. Both intraday and interday validations of fragment sizing and quantitation have also been performed with a 7500 Assay Kit (n = 48). Although the results of quantitation are not as good as that of sizing, due to the manual introduction of samples and markers into the chip wells, they are still sufficient to carry out further analyses of practical samples. Based on such reliable results, fast analysis of DNA polymorphisms on the human Y-chromosome has been realized with microchip electrophoresis. The total analysis times of three genomic polymorphisms on the Y-chromosome, Y Alu polymorphism, 47z/StuI, and 12f2, are all within 100 s, and the relative standard deviation and relative error of fragment sizes are below 3.5 and 3.7%, respectively. In addition, a mixture of nine DNA markers on the human Y-chromosome related to examine the cause of spermatogenic failure have been separated successfully with the smallest fragment size difference of 7 bp. Our results demonstrate the potential of microchip electrophoresis in polymorphism analysis with the advantages of high speed, good reproducibility, high precision, and high resolution.     

Separation and analysis of DNA sequence reaction products by capillary gel electrophoresis

This paper demonstrates the potential of capillary gel electrophoresis with laser induced fluorescence detection as a tool for DNA sequence determination. Both synthetic oligonucleotides and single-stranded phage DNA were utilized as templates in the standard chain termination procedure. Primer molecules were tagged at the 5' end with the fluorescent dye, JOE. First, baseline resolution of a dA extended primer from 18 to 81 bases long, a total of 64 fragments, was observed. A second synthetic template was designed to yield alternating stretches of dA and dT extensions of the primer. Thirdly, the sequence reaction products from a synthetic oligonucleotide template containing all four bases was analyzed in four independent runs, one for each of the four base-specific reactions. In all cases, the expected number and patterns of peaks were observed by capillary gel electrophoretic analysis. Finally, separation of sequence reaction products generated with single-strand M13mp18 phage DNA as template exhibited baseline resolution of fragments differing in length by a single nucleotide and from 18 to greater than 330 bases total length.     

Use of denaturing gradient gel electrophoresis to detect mutation in VS2 of the 16S-23S rDNA spacer amplified from Staphylococcus aureus isolates

To develop a double gradient denaturing gradient gel electrophoresis (DG-DGGE) based typing method that rapidly and accurately types clinical isolates of Staphylococcus aureus, the VS2 region of the 16S-23S rRNA spacer region (ISR) was chosen because of its potential high variation. The VS2 region was amplified with a 40-mer GC-clamp attached to the 5'-end of the reverse primer. The 145 bp PCR product was then separated by DG-DGGE using denaturant concentrations of 25-40% and polyacrylamide concentrations of 6-12%. Of the five mutations identified in 336 S. aureus isolates, one mutation was found to be highly specific for 161/171 (94%) of methicillin-resistant S. aureus (MRSA) isolates from different geographic locations and isolation times. This same mutation was found in 15/160 (9%) of penicillin- or methicillin-sensitive S. aureus isolates. In some isolates two mutations occured together in the one genome suggesting some S. aureus isolates have two copies of VS2. In these 336 isolates nine genotypes with different combinations of the five mutations were identified. In 18 coagulase-negative staphylococci (CNS), the MRSA-specific mutation was found along with two other mutations in all isolates demonstrating consistent differences in the presence of these mutations between CNS and S. aureus. The marked differences in VS2 sequences found between MRSA, methicillin- or penicillin-sensitive S. aureus (SSA), and CNS by DGGE in the present study may be useful in evolutionary studies and in the development of a specific assay for MRSA from clinical specimens.     

Distinction between supercoiled and linear DNA in transverse agarose pore gradient gel electrophoresis.

Four species of linear DNA and the first four members of a linking series, generated by treatment of plasmid DNA (PUC19, 2.7 kb) with mitochondrial topoisomerase I, were differentiated by transverse agarose pore gradient gel electrophoresis. The experimental curves of migration distance vs. agarose concentration (Ferguson curves) of supercoiled DNA exhibit a steeper trajectory than those of linear DNA of the same size range. As a consequence, the four supercoiled species exhibit an increase in apparent size (relative to linear DNA standards) with increasing agarose concentration. Both the crossing of the Ferguson curves with those of linear standards as well as the apparent size increase with agarose concentration can serve to detect supercoiled plasmid-sized DNA in mixtures with linear DNA.     

Dynamics of single-stranded DNA migration in denaturing polyacrylamide slab-gel electrophoresis

We describe an original apparatus for the study of the dynamics of single stranded DNA migration. Four detectors based on laser-induced fluorescence (LIF) are equidistantly placed on one migration lane, allowing repeated measurements of the same DNA band at different positions along migration. This article presents the characteristics and performances of this system and focuses on the data analysis, showing how the multiple detection scheme enables the study of band broadening and band resolution during a migration run. Our results suggest the existence of anomalous (nonthermal) diffusion of DNA molecules during the electrophoretic process.     

Polyacrylamide gel electrophoresis of proteoglycans in large-pore gradient gels

A procedure is described for preparing large-pore polyacrylamide gradient gels (1.2–16% T, 10–4% C) that allow the separation of large proteoglycans of molecular mass up to several millions.     

Density gradient electrophoresis of cells in a reversible gel

Density gradient electrophoresis permits the separation of cell types according to surface charge density with high resolution. Any source of flow compromises the resolving power of density gradient electrophoresis. Although procedures have been devised to successfully counteract electroosmotic and convective flows, the final collection of separands requires that they be pumped out of the electrophoresis column. Experiments were therefore designed to test the hypothesis that this flow could also be eliminated by trapping the separated bands in a gel, from which they could be collected by slicing the gel cylinder. Glutaraldehyde-fixed rat and rabbit erythrocytes were used as test particles in a phosphate-buffered isotonic Ficoll-sucrose density gradient in a 2.2 cm diameter, thermostated vertical glass column that could be opened at both ends. Two types of agarose were used as gel polymers: Electrophoresis grade agarose (J.T. Baker Chemical Co.) at final concentrations of 0.1 to 0.25% and SeaPrep ultralow gelling agarose (Marine Colloids Div., FMC Corp.) at a final concentration of 1.0%. Electrophoretic separability of the test particles and fluid stability were tested independently at 55 degrees C and 32 degrees C at which the two agaroses were, respectively, liquid. The experiments demonstrated that the higher temperatures required and the presence of agarose compromised neither the stability of the density gradient nor the migration properties of the cells, and cells can be separated in a sol at a temperature that is compatible with cell viability.     

A fuzzy distance metric for measuring the dissimilarity of planar chromatographic profiles with application to denaturing gradient gel electrophoresis data from human skin microbes: demonstration of an individual and gender-based fingerprint

A newly devised fuzzy metric for measuring the dissimilarity between two planar chromatographic profiles is proposed in this paper. It does not require an accurately assigned sample-feature matrix and can cope with slight imprecision of the positional information. This makes it very suitable for 1-D techniques which do not have a second spectroscopic dimension to aid variable assignment. The usefulness of this metric has been demonstrated on a large data set consisting of nearly 400 samples from Denaturing Gradient Gel Electrophoresis (DGGE) analysis of microbes on human skin. The pattern revealed by this dissimilarity metric was compared with the one represented by a sample-feature matrix and highly consistent results were obtained. Several pattern recognition techniques have been applied on the dissimilarity matrix based on this dissimilarity metric. According to rank analysis, within-individual variation is significantly less than between-individual variation, suggesting a unique individual microbial fingerprint. Principal Coordinates Analysis (PCO) suggests that there is a considerable separation between genders. These results suggest that there are specific microbial colonies characteristic of individuals.     

Detection of DNA curvature by transverse pore gradient gel electrophoresis on PhastSystem gels.

It has been known since 1990 that DNA curvature can be recognized on transverse pore gradient gels by an intersection of "Ferguson curves" with those of DNA size standards. The miniaturized PhastSystem polyacrylamide gels allow one to detect DNA curvature effortlessly and fast and at great economy of sample relative to alternative methods of electrophoresis. Using the transverse gradient gel electrophoresis method, it was found that the 660 bp length subfragment of the matrix attachment region (MAR) sequence of the chicken lysosyme gene migrates as a fragment of 800-900 bp length. When subjected to digestion with the restriction enzyme HaeIII, the fragment gives rise to two species of 248 and 412 bp length, respectively. The Ferguson curves of both species intersect with those of DNA size standards, indicating that both exhibit curvature. Only the curvature of the 412 bp fragment conforms to prediction. Ethidium bromide abolishes the effect of curvature on the fragment, reducing its apparent size from 900 to 660, the value obtained by agarose gel electrophoresis.     

Mobility surfaces for field-inversion gel electrophoresis of linear DNA

The mobility of linear DNA during field-inversion gel electrophoresis was measured as a function of molecular weight Mr, pulse time t, and field strength E. Values of Mr between 48.5 and 194 kilobase pairs (kb), E from 5 to 14 V/cm and pulse times of 0.3 to 12 s were used. The data are presented as three-dimensional surfaces of mobility: E:t for fixed Mr or graphs of mobility: Mr:t for fixed E. The surfaces are not smoothly increasing functions of E, Mr, or t but instead show a valley with minimum mobility and a steep rise in mobility as t increases. For a field of 10 V/cm, 1% agarose gels, and 3:1 ratio of forward:back pulse time, the forward switching time t* at which the mobility changes most rapidly is given by t* = (0.034 +/- 0.003) Mr for Mr in kb and t* in seconds. The data and equations delineate the best conditions to achieve a particular separation.