Mutation screening using fluorescence multiplex denaturing gradient gel electrophoresis (FMD): detecting mutations in the BRCA1 gene

Fluorescent multiplex denaturing gradient gel electrophoresis (FMD) is a mutation screening technique designed to detect unknown as well as previously identified mutations. FMD constitutes a recent modification of the standard denaturing gradient gel electrophoresis (DGGE) technique, which combines multiplex PCR amplification of target DNA using fluorescently labeled primers with DGGE separation of the amplicon mixture, allowing immediate identification of sequence variants by wet gel scanning. FMD permits the simultaneous detection of small insertions, deletions and single nucleotide substitutions among multiple DNA fragments (up to 480 fragments) from 96 samples in parallel for each run. It increases output and reduces cost dramatically compared with classical DGGE, without sacrificing sensitivity and accuracy in detecting mutations. This protocol details an accurate, fast, nonradioactive and cost-effective way to screen the BRCA1 gene for mutations with high sensitivity, providing easily interpreted results. It may also be adapted to screen other target genes and/or used in large-scale epidemiological studies.     

Rapid photometric detection of thymine residues partially flipped out of double helix as a method for direct scanning of point mutations and apurinic DNA sites

A spectroscopic assay for detection of extrahelical thymine residues in DNA heteroduplexes under their modification by potassium permanganate has been developed. The assay is based on increase in absorbance at 420 nm due to accumulation of thymidine oxidation intermediates and soluble manganese dioxide. The analysis was carried out using a set of 19-bp DNA duplexes containing unpaired thymidines opposite tetrahydrofuranyl derivatives mimicking a widespread DNA damage (apurinic (AP) sites) and a library of 50-bp DNA duplexes containing all types of base mismatches in different surroundings. The relation between the selectivity of unpaired T oxidation and the thermal stability of DNA double helix was investigated. The method described here was shown to discriminate between DNA duplexes with one or two AP sites and to reveal thymine-containing mismatches and all noncanonical base pairs in AT-surroundings. Comparative results of CCM analysis and the rapid photometric assay for mismatch detection are demonstrated for the first time in the same model system. The chemical reactivity of target thymines was shown to correlate with local disturbance of double helix at the mismatch site. As the spectroscopic assay does not require the DNA cleavage reaction and gel electrophoresis, it can be easily automated and used for primary screening of somatic mutations.     

DNA base mismatch detection with bulky rhodium intercalators: synthesis and applications

This protocol describes the syntheses and applications of two metallointercalators, Rh(bpy)2(chrysi)3+ and Rh(bpy)2(phzi)3+, that target single base mismatches in DNA. The complexes bind mismatched DNA sites specifically and, upon photoactivation, promote strand scission neighboring the mismatch. Owing to their high specificity and sequence context independence, targeting mismatches with these complexes offers an attractive alternative to current mismatch- and SNP-detection methodologies. This protocol also describes the synthesis of these complexes and their use in marking mismatched sites. Irradiation of 32P-labeled duplex DNA with either intercalator followed by denaturing PAGE allows the detection of mismatches in oligonucleotides. The protocol also outlines a method for efficient detection of single nucleotide polymorphisms (SNPs) in larger genes or plasmids. Pooled genes are denatured and re-annealed to form heteroduplexes; they are then incubated with either complex, irradiated and analyzed using capillary electrophoresis to probe for mismatches (SNP sites). The synthesis of the metallointercalators requires approximately 5-7 d. The mismatch- and SNP-detection experiments each require approximately 3 d.     

Unexpected behavior of H2Kb mutant DNAs in denaturing gradient gel electrophoresis.

Denaturing gradient gel electrophoresis (DGGE) is based upon the different melting behaviors of DNA molecules in a chemical denaturant gradient according to their sequences. This technique has recently become a widespread tool to detect mutations. The introduction of a GC-clamp enables the detection of most single base differences between two DNA molecules. As a test system we have applied the polymerase chain reaction (PCR) in combination with DGGE to detect a number of mutations in the mouse H2Kb DNA sequence. A wide variety of spontaneous in vivo mutations of this haplotype have been reported in the C57BL/6J mouse strain and are clustered in the alpha 1 and alpha 2 domains. The combination of PCR and DGGE revealed almost all base changes present in the H2Kb mutants used. However, most of the PCR products of these mutants showed melting behavior which is not easily predicted. We suggest that in addition to current simple theory, which considers that the migration of a DNA molecule in a denaturing gradient depends primarily on its initial melting behavior, additional factors such as secondary structure in partially melted molecules may play a role and can be used to detect mutations.     

Comprehensive, rapid and sensitive detection of sequence variants of human mitochondrial tRNA genes.

In the present study, a comprehensive, rapid and sensitive method for screening sequence variation of the human mitochondrial tRNA genes has been developed. For this purpose, the denaturing gradient gel electrophoresis (DGGE) technique has been appropriately modified for simultaneous mutation analysis of a large number of samples and adapted so as to circumvent the problems caused by the anomalous electrophoretic behavior of DNA fragments encoding tRNA genes. Eighteen segments of mitochondrial DNA (mtDNA), each containing a single uniform melting domain, were selected to cover all tRNA-encoding regions using the computer program MELT94. All 18 segments were simultaneously analyzed by electrophoresis through a single broad range denaturing gradient gel under rigorously defined conditions, which prevent band broadening and other migration abnormalities from interfering with detection of sequence variants. All base substitutions tested, which include six natural mutations and 14 artificially introduced ones, have been detected successfully in the present study. Several types of evidence strongly suggest that the anomalous behavior in DGGE of tRNA gene-containing mtDNA fragments reflects their tendency to form temporary or stable alternative secondary structures under semi-denaturing conditions. The high sensitivity of the method, which can detect as low as 10% of mutant mtDNA visually, makes it valuable for the analysis of heteroplasmic mutations.     

High-throughput conformation-sensitive gel electrophoresis for discovery of SNPs

High-throughput screening for single nucleotide polymorphisms (SNPs) or mutations can be achieved by inexpensive technologies. We modified the original protocols of conformation-sensitive gel electrophoresis (CSGE) to increase throughput several fold to 1.3 samples/min, which is about five times faster than denaturing high-performance liquid chromatography (DHPLC). The modifications include decreasing the gel thickness, increasing the number of lanes to 96, and increasing the number of samples per lane to seven. This high-throughput CSGE method is fast, robust, and as simple as the original protocols. Together with a two-stage strategy for screening homozygotes and the replacement of ethidium bromide with SYBR Gold DNA dye staining, this protocol is a reliable and cost-effective alternative for laboratories that require high-throughput screening.     

Single-strand conformation polymorphism analysis using capillary array electrophoresis for large-scale mutation detection

This protocol describes capillary array electrophoresis single-strand conformation polymorphism (CAE-SSCP), a screening method for detection of unknown and previously identified mutations. The method detects 98% of mutations in a sample material and can be applied to any organism where the goal is to determine genetic variation. This protocol describes how to screen for mutations in 192 singleplex or up to 768 multiplex samples over 3 days. The protocol is based on the principle of sequence-specific mobility of single-stranded DNA in a native polymer, and covers all stages in the procedure, from initial DNA purification to final CAE-SSCP data analysis, as follows: DNA is purified, followed by PCR amplification using fluorescent primers. After PCR amplification, double-stranded DNA is heat-denatured to separate the strands and subsequently cooled on ice to avoid reannealing. Finally, samples are analyzed by capillary electrophoresis and appropriate analysis software.     

Two dimensional single-strand conformation polymorphism analysis: a useful tool for the detection of mutations in long DNA fragments.

A new two-dimensional gel system for the analysis of single strand conformational polymorphisms has been developed to identify point mutations, deletions and insertions in long DNA fragments (e.g. 2.7 kb) generated by the polymerase chain reaction. In this procedure, such DNA fragments are first restricted with frequent-cutter enzymes. The resulting small fragments are then separated in the first dimension according to their size by electrophoresis under denaturing conditions; these single stranded DNA fragments are subsequently fractionated in the second dimension by electrophoresis on a non denaturing slab gel based on their fold-back conformation which is completely sequence-dependent. The method was tested on three previously characterized pH 4.5 resistant mutants of HRV14 and was then used to determine changes in three further mutants.     

Prevalence of three mutations in the Gs alpha gene among 24 families with pseudohypoparathyroidism type Ia.

Pseudohypoparathyroidism type Ia (PHP-Ia), an inherited multi-hormone resistance syndrome, is associated with deficient cellular activity of the alpha-subunit of the guanine nucleotide-binding protein (Gs alpha) that stimulates adenylyl cyclase. We determined prevalence of three recently described mutations in exons 1 and 10 of the Gs alpha gene among 24 unrelated patients with PHP-Ia. Restriction analysis was used to detect two mutations that produce unique RFLPs, and allele-specific oligonucleotide hybridization was used to detect the other mutation. As none of these mutations were not found, genomic DNA was analyzed with denaturing gradient gel electrophoresis to screen for other mutations in exon 10. Mutations of the initiation codon and exon 10 in the Gs alpha gene thus rarely (< or = 4% each) cause PHP-Ia and the Gs alpha gene mutations causing PHP-Ia are heterogeneous and unique to each pedigree.     

Detection of DNA sequence polymorphisms in human genomic DNA by using denaturing gradient gel blots.

Denaturing gradient gel electrophoresis can detect sequence differences outside restriction-enzyme recognition sites. DNA sequence polymorphisms can be detected as restriction-fragment melting polymorphisms (RFMPs) in genomic DNA by using blots made from denaturing gradient gels. In contrast to the use of Southern blots to find sequence differences, denaturing gradient gel blots can detect differences almost anywhere, not just at 4-6-bp restriction-enzyme recognition sites. Human genomic DNA was digested with one of several randomly selected 4-bp recognition-site restriction enzymes, electrophoresed in denaturing gradient gels, and transferred to nylon membranes. The blots were hybridized with radioactive probes prepared from the factor VIII, type II collagen, insulin receptor, beta 2-adrenergic receptor, and 21-hydroxylase genes; in unrelated individuals, several RFMPs were found in fragments from every locus tested. No restriction map or sequence information was used to detect RFMPs. RFMPs can be used as genetic markers, because their alleles segregate in a Mendelian manner. Unlike most other methods for detecting DNA sequence polymorphisms, a genomic DNA blot made from one gel can be hybridized consecutively with many (30 or more) different probes.     

Novel method of detecting single base substitutions in RNA molecules by differential melting behavior in solution

We have developed a quick and reliable way of detecting point mutations in RNA molecules. This method involves melting RNA-RNA heteroduplexes of varying lengths in a series of tubes containing a stepwise salt or formamide gradient, followed by polyacrylamide gel electrophoresis to distinguish between single- and double-stranded RNA molecules. The manipulations required are technically simple, and the method is sensitive enough to detect destabilization of the highest melting domain of a dsRNA duplex by a single base mismatch. When this method is used in parallel with denaturing gradient gel electrophoresis, which detects point mutations in low-melting domains of duplexes, it should now be possible to rapidly screen for mutations located throughout the length of any RNA molecule whose wild-type sequence is known.     

Comprehensive detection of single base changes in human genomic DNA using denaturing gradient gel electrophoresis and a GC clamp

We present a simple, efficient extension of denaturing gradient gel electrophoresis that allows the detection of nearly any sequence change in a defined fragment of DNA. The fragment can be obtained either by means of the polymerase chain reaction or by restriction digestion of genomic DNA. With restriction fragments of genomic DNA, sequence information is not required, and covalent modifications in genomic DNA that are lost in a PCR, such as methylation, are detectable. We describe how a GC clamp (an arbitrary, G+C-rich sequence of 30 to 60 bp) can be attached to a selected restriction fragment present in a digest of genomic DNA. The GC clamp alters the melting properties of the fragment; this change greatly increases the fraction of possible mutations that is detectable. In a 272-bp HaeIII fragment from the human beta-globin gene, we were able to detect 13 of 13 mutations tested in human genomic DNA. Four additional mutations in cloned plasmids were analyzed. The data agree with a simple theoretical model for DGGE, which predicts how two fragments, differing at a single (specified) base pair, are resolved in a gradient gel as a function of running time for the gel. The calculation assists in the design of probes and gel conditions that aid in the detection of sequence changes.     

Rapid screening of the entire mitochondrial DNA for low-level heteroplasmic mutations

Alterations of the mitochondrial DNA (mtDNA) are implicated in various pathological conditions. In this study, we used denaturing high performance liquid chromatography (DHPLC) as a method to rapidly screen the entire mtDNA for mutations. Overlapping DNA fragments, amplified by one single cycling protocol from frozen pre-formulated PCR mixes, were subjected to DHPLC analysis. Single DHPLC injections of fragments yielded straightforward interpretation of results with a detection limit down to 1% mtDNA heteroplasmy. Furthermore, collection and re-amplification of low degree heteroduplex peak-fractions allowed sequence analysis of mtDNA mutations down to the detection limit of the DHPLC method. In order to demonstrate that the method has diagnostic value, we analyzed and confirmed known mtDNA mutations in patient samples.     

Southern blotting

This protocol describes a basic method to perform the Southern blot. Blotting allows the detection of specific molecules among a mixture separated by gel electrophoresis. Molecules are transferred from the gel to a porous membrane by capillary action using absorbent paper to soak solution through the gel and the membrane. For DNA, specific sequences are detected in the membrane by molecular hybridization with labeled nucleic acid probes. The original method, on which this protocol is based, used labeled RNAs to detect specific DNA fragments in genomic DNA that had been digested with restriction endonucleases. This protocol can be completed in 1-5 d and is inexpensive to carry out, as it requires only basic laboratory equipment.     

Absence of mutations in the promoter region of the low density lipoprotein receptor gene in a large number of familial hypercholesterolaemia patients as revealed by denaturing gradient gel electrophoresis

Summary Denaturing gradient gel electrophoresis (DGGE) was used in combination with the polymerase chain reaction (PCR) to detect sequence variations in the promoter region of the low density lipoprotein receptor (LDLR) gene. On the basis of calculated predictive melting properties we designed primers to amplify a 447-bp fragment of the promoter region from position-512 to -66, containing previously identified regulatory sequences. Using a primer with a GC-clamp in combination with restriction enzyme digestion, two melting domains could be analysed simultaneously. By oligonucleotide-directed mutagenesis artificial mutants were generated to optimize the conditions and to test the sensitivity of the method. All mutants were readily detected by electrophoresis in a 9% polyacrylamide gel containing a 10%–60% linear denaturing gradient. Using this method, we analysed DNA samples of 350 heterozygous familial hypercholesterolaemia (FH) patients. No mutations were detected, suggesting that mutations in the regulatory elements of the promoter sequence do not play a significant role in the etiology of FH.     

Mutation detection using immobilized mismatch binding protein (MutS).

An accurate and highly sensitive mutation detection assay has been developed. The assay is based on the detection of mispaired and unpaired bases by immobilized mismatch binding protein (Escherichia coli MutS). The assay can detect most mismatches and all single base substitution mutations, as well as small addition or deletion mutations. The assay is simple to use and does not require the use of either radioactivity or gel electrophoresis.     

Isolation and purification of microbial community DNA from soil naturally enriched for chitin

We made an attempt to isolate and purify metagenomic DNA from chitin enriched soil. In this communication we report a modified direct lysis method for soil DNA extraction including initial pre-lysis washing of sample, followed by a rapid polyvinylpyrrolidone-agarose-based purification and electroelution of DNA using Gene-capsule™ assembly. Rapidity was achieved using low molarity conducting media (sodium-borate buffer) for electrophoresis by reducing run time for both the gel electrophoresis and electroelution. Extracted DNA was sufficiently pure and of high quality, evidenced by amplification of 16S rDNA and chitinase genes by PCR. Metagenomic nature of the DNA was confirmed by running V3 (16S rDNA) region amplicons using denaturing gradient gel electrophoresis. This method requires 30 min for purification, and less than 2 h for complete execution of protocol and becomes the first report on the isolation of metagenomic DNA from soil naturally enriched for chitin.     

Analysis of sequence alterations in a defined DNA region: comparison of temperature-modulated heteroduplex analysis and denaturing gradient gel electrophoresis

The ability to detect DNA sequence heterogeneity quickly and reliably is becoming increasingly important as more genes involved in disease processes are discovered. We have assessed the ability of a high pressure liquid chromatography technique (HPLC) termed temperature-modulated heteroduplex analysis (TMHA) to detect a collection of 20 point mutations distributed throughout a 279 base pair fragment spanning the exon 8 region of the human HPRT gene. All mutant/wild type heteroduplexes formed from mutations in the lowest temperature melting domain of the fragment were easily resolved from the corresponding mutant and wt homoduplexes, while those generated from mutants in the next higher melting domain barely resolved from their parental homoduplexes. For comparison, identical heteroduplex samples were subjected to denaturing gradient gel electrophoresis (DGGE). Heteroduplexes in the lowest temperature melting domain were easily resolved, while no resolution was achieved with those in the next higher melting domain. These results suggest that TMHA and DGGE are measuring similar melting characteristics in heteroduplex molecules. TMHA appears to be a robust approach for detecting and/or purifying a wide variety of mutations in a defined region of DNA, provided that the melting characteristics of the fragment under study are carefully considered.     

A Simple CELI Endonuclease-Based Protocol for Genotyping both SNPs and InDels

Modern genetic analyses rely on efficient genotyping of single-nucleotide polymorphisms (SNP) or insertion/deletion length polymorphisms (InDel) in genomes. Methods available to genotype these polymorphisms include sequencing, cleaved amplified polymorphic sequence, high-resolution DNA melting, and microarray analyses, which are all rather tedious or expensive to set up for daily use. Here, we report a simplified label-free CELI endonuclease (CELI)-based protocol that enables us to detect both SNPs and InDels for fragment lengths between 500 and 6 kb. PCR-amplified target DNA fragments were annealed, cleaved by CELI, and analyzed either cost-effectively by agarose gel electrophoresis or automatically by capillary electrophoresis. The optimal amplification sizes, potential blind ends, and the maximum pooling capacities were examined for both electrophoresis protocols. We believe that the CELI-based genotyping protocol can be used in the detection of mutations, marker-assisted breeding, map-based cloning, and genome-wide association studies.