High-speed, multicolor fluorescent two-dimensional gene scanning.

Two-dimensional gene scanning (TDGS) is a method for analyzing multiple DNA fragments in parallel for all possible sequence variations, using extensive multiplex PCR and two-dimensional electrophoretic separation on the basis of size and melting temperature. High throughput application of TDGS is limited by the prolonged time periods necessary to complete the second-dimension electrophoretic separation step--denaturing gradient gel electrophoresis--and the current need for gel staining. To address these problems, we constructed a high-voltage, automatic, two-dimensional electrophoresis system and used this in combination with thinner gels to reduce two-dimensional electrophoresis time about 80%. Instead of gel staining, we used three different fluorophores to simultaneously analyze three samples in the same gel. These improvements greatly increase TDGS speed and throughput and make the method highly suitable for large-scale single-nucleotide polymorphism discovery and genetic testing.     

The use of capillary electrophoresis for DNA polymorphism analysis

Capillary electrophoresis has advanced enormously over the last 10 yr as a tool for DNA sequencing, driven by the human and other major genome projects and by the need for rapid electrophoresis-based DNA diagnostic tests. The common need of these analyses is a platform providing very high throughput, high-quality data, and low process costs. These demands have led to capillary electrophoresis machines with multiple capillaries providing highly parallel analyses, to new electrophoresis matrices, to highly sensitive spectrofluorometers, and to brighter, spectrally distinct fluorescent dyes with which to label DNA. Capillary devices have also been engineered onto microchip formats, on which both the amount of sample required for analysis and the speed of analysis are increased by an order of magnitude. This review examines the advances made in capillary and chip-based microdevices and in the different DNA-based assays developed for mutation detection and genotype analysis using capillary electrophoresis. The automation of attendant processes such as for DNA sample preparation, PCR, and analyte purification are also reviewed. Together, these technological developments provide the throughput demanded by the large genome-sequencing projects.     

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.     

Molecular quantification of genes encoding for green-fluorescent proteins

A quantitative PCR approach is presented to analyze the amount of recombinant green fluorescent protein (gfp) genes in environmental DNA samples. The quantification assay is a combination of specific PCR amplification and temperature gradient gel electrophoresis (TGGE). Gene quantification is provided by a competitively coamplified DNA standard constructed by point mutation PCR. A single base difference was introduced to achieve a suitable migration difference in TGGE between the original target DNA and the modified standard without altering the PCR amplification efficiency. This competitive PCR strategy is a highly specific and sensitive way to monitor recombinant DNA in environments like the efflux of a biotechnological plant.     

Detection of point mutations associated with genetic diseases by an exon scanning technique

A major challenge in genetics is identifying the basis of human heritable disease. We describe an "exon scanning" technique which surveys exons in genomic DNA for sequence alterations. By hybridizing genomic DNA to RNA probes derived from cDNAs, we can use RNase A to survey entire coding regions, comprising exons spread across extensive regions of genomic DNA, for mutations associated with genetic disease. Exon scanning of the beta-globin locus in the DNA of patients with 12 different hemoglobinopathies detected all of the culpable single base substitutions and deletions, but not single base insertions. Our analysis also revealed unsuspected polymorphisms and corrected a diagnosis originally based on hemoglobin electrophoresis. Exon scanning of the ornithine aminotransferase gene in a gyrate atrophy patient detected and localized a mutation in the sixth exon. Subsequent PCR amplification and sequencing characterized this as a missense mutation (proline----glutamine). Exon scanning of genomic DNA for sequence alterations, in combination with PCR amplification and sequencing, should be a generally useful strategy for evaluating suspect genes in disorders of unknown etiology, as well as for clinical diagnosis.     

Rapid design of denaturing gradient-based two-dimensional electrophoretic gene mutational scanning tests.

With the current rapid pace at which human disease genes are identified there is a need for practical, cost-efficient genetic screening tests. Two-dimensional electrophoretic separation of PCR-amplified gene fragments on the basis of size and base pair sequence, in non-denaturing and denaturing gradient polyacrylamide gels respectively, provides a rapid parallel approach to gene mutational scanning. Accuracy of the denaturing gradient gel electrophoresis (DGGE) component of this system strongly depends on the design of the PCR primers and the melting characteristics of the fragments they encompass. We have developed a fully automated generally applicable procedure to generate optimal two-dimensional test designs at a minimum amount of time and effort. Designs were generated for the RB1 , TP53 , MLH1 and BRCA1 genes that can be readily implemented in research and clinical laboratories as low cost genetic screening tests.     

Rapid identification of Arabidopsis insertion mutants by non-radioactive detection of T-DNA tagged genes

To assist in the analysis of plant gene functions we have generated a new Arabidopsis insertion mutant collection of 90 000 lines that carry the T-DNA of Agrobacterium gene fusion vector pPCV6NFHyg. Segregation analysis indicates that the average frequency of insertion sites is 1.29 per line, predicting about 116 100 independent tagged loci in the collection. The average T-DNA copy number estimated by Southern DNA hybridization is 2.4, as over 50% of the insertion loci contain tandem T-DNA copies. The collection is pooled in two arrays providing 40 PCR templates, each containing DNA from either 4000 or 5000 individual plants. A rapid and sensitive PCR technique using high-quality template DNA accelerates the identification of T-DNA tagged genes without DNA hybridization. The PCR screening is performed by agarose gel electrophoresis followed by isolation and direct sequencing of DNA fragments of amplified T-DNA insert junctions. To estimate the mutation recovery rate, 39 700 lines have been screened for T-DNA tags in 154 genes yielding 87 confirmed mutations in 73 target genes. Screening the whole collection with both T-DNA border primers requires 170 PCR reactions that are expected to detect a mutation in a gene with at least twofold redundancy and an estimated probability of 77%. Using this technique, an M2 family segregating a characterized gene mutation can be identified within 4 weeks.     

Automated DNA mutation analysis by single-strand conformation polymorphism using capillary electrophoresis with laser-induced fluorescence detection

Automation is essential for rapid genetic-based mutation analysis in clinical laboratory to screen a large number of DNA samples. We propose in this report an automatic process using Beckman Coulter P/ACE™ capillary electrophoresis (CE) with laser-induced fluorescence (LIF) system to detect a single-point mutation in the codon 12 of human K-ras gene. Polymerase chain reaction (PCR) using a fluorescently labeled reverse primer and a plain forward primer to specifically amplify a selected 50 bp DNA fragment in human K-ras gene. The amplified DNA is placed on the sample tray of the CE system with a pre-programmed step for single-strand conformation polymorphism (SSCP) analysis. Sample injection and denaturation processes are performed online along with separation and real-time data analysis. The concept of automation for rapid DNA mutation analysis using CE-LIF system for SSCP is presented.     

Analysis of disease-causing genes and DNA-based drugs by capillary electrophoresis towards DNA diagnosis and gene therapy for human diseases

Rapid progress in the Human Genome Project has stimulated investigations for gene therapy and DNA diagnosis of human diseases through mutation or polymorphism analysis of disease-causing genes and has resulted in a new class of drugs, i.e., DNA-based drugs, including human gene, disease-causing gene, antisene DNA, DNA vaccine, triplex-forming oligonucleotide, protein-binding oligonucleotides, and ribozyme. The recent development of capillary electrophoresis technologies has facilitated the application of capillary electrophoresis to the analysis of DNA-based drugs and the detection of mutations and polymorphism on human genes towards DNA diagnosis and gene therapy for human diseases. In this article the present state of studies on the analysis of DNA-based drugs and disease-causing genes by capillary electrophoresis is reviewed. The paper gives an overview of recent progress in the Human Genome Project and the fundamental aspects of polymerase chain reaction-based technologies for the detection of mutations and polymorphism on human genes and capillary electrophoresis techniques. Attention is mainly paid to the application of capillary electrophoresis to polymerase chain reaction analysis, restriction fragment length polymorphism, single strand conformational polymorphism, variable number of tandem repeat, microsatellite analysis, hybridization technique, and monitoring of DNA-based drugs. Possible future trends are also discussed.     

Multiplex polymerase chain reaction amplification and direct sequencing of homologous sequences: point mutation analysis of the ras genes.

ras proto-oncogenes are activated by point mutation in a wide variety of human and animal tumors, making ras gene analysis a major area of clinical and basic cancer research. Activating point mutations, in each of the three ras genes (Ha-, Ki-, or N-ras), usually occur in one of three specific codons (12, 13, or 61). Thus, an adequate assessment of activating ras gene mutations should include the analysis of at least nine codons. We have developed a rapid method for point mutation analysis of the ras genes, which involves simultaneous (multiplex) PCR amplification of all three homologous ras genes (in the regions surrounding codons 12-13 and codon 61) in a single reaction starting with only 1 microgram of genomic DNA. Although multiplex PCR has been previously used for unrelated sequences, we demonstrate here that multiplex PCR can also be used for highly homologous sequences. Importantly, after coamplification, each of the homologous ras genes can be individually and specifically sequenced even though the other two closely related genes are present in the same template mixture, by using high-stringency conditions permitted by Taq DNA polymerase. An automated multicycle DNA sequencing procedure is used to allow the double-stranded PCR products to be sequenced directly without the need to generate single-stranded templates, further simplifying the protocol. Our multiplex PCR amplification and direct DNA sequencing procedures should greatly facilitate more complete analyses of activating ras gene point mutations, particularly in studies involving many tumor samples.(ABSTRACT TRUNCATED AT 250 WORDS)     

Exon concatenation to increase the efficiency of mutation screening by DGGE

For genes that have a substantial number of exons and long intronic sequences, mutation screening by denaturing gradient gel electrophoresis (DGGE) requires the amplification of each exon from genomic DNA by PCR. This results in a high number of fragments to be analyzed by DGGE so that the analysis of large sample sets becomes labor intensive and time consuming. To address this problem, we have developed a new strategy for mutation analysis, lexon-DGGE, which combines the joining of different exons by PCR (also known as lexons) with a highly sensitive technique such as DGGE to screen for mutations. The lexon technique is based on the concatenation of several exons, adjacent or not, from genomic DNA into a single DNA fragment so that this approach could simultaneously be used to check the mutational status of several small genes. To show the feasibility of the approach, we have used the lexon-DGGE technique to analyze all coding exons, intron-exon junctions, noncoding exon 1, and part of the noncoding region of exon 11 of the TP53 gene. The validity and performance of the technique were confirmed by using negative and positive controls for each of the DNAfragments analyzed.     

Lipoprotein lipase genotypes for a common premature termination codon mutation detected by PCR-mediated site-directed mutagenesis and restriction digestion.

We have developed a procedure for the determination of a common mutation in exon 9 of the human lipoprotein lipase (LPL) gene. The mutation is due to a C-G transversion which creates a premature termination codon (Ser447-Ter) and results in a truncated LPL molecule lacking the C-terminal dipeptide SER-GLY. The mutation can be detected by polymerase chain reaction (PCR) amplification of exon 9 using a modified 3' amplimer that produces a 140 bp product containing a site for the restriction enzyme Hinf-1 in the presence of the mutation (G allele). The G allele was in strong linkage disequilibrium with a Hind-III restriction fragment length polymorphism (RFLP) allele in intron 8. Genotype determinations for the mutation can be performed by PCR amplification of genomic DNA, digestion with Hinf-1, and analysis of the products by polyacrylamide gel electrophoresis. The allelic frequency of the Ser447-Ter mutation in normal male Caucasian controls was 0.11. The frequency of the mutation was lower in a group of subjects with primary hypertriglyceridemia compared to normolipidemic controls.     

One multiplex control for 29 cystic fibrosis mutations

A simple approach is described to synthesize and clone an inexhaustible supply of any homozygous and/or heterozygous controls diluted with yeast genomic DNA to mimic human genome equivalents for use throughout the entire multiplex mutation assay. As a proof of principle, the 25 cystic fibrosis mutation panel selected by the American College of Medical Genetics and four additional mutant sequences were prepared as a single control mixture. The 29 CFTR mutations were incorporated into 17 gene fragments by PCR amplification of targeted sequences using mutagenic primers on normal human genomic DNA template. Flanking primers selected to bind beyond all published PCR primer sites amplified controls for most assay platforms. The 17 synthesized 433-933-bp CFTR fragments each with one to four homozygous mutant sequences were cloned into nine plasmid vectors at the multiple cloning site and bidirectionally sequenced. Miniplasmid preps from these nine clones were mixed and diluted with genomic yeast DNA to mimic the final nucleotide molar ratio of two CFTR genes in 6 x 10(9) bp total human genomic DNA. This mixture was added to control PCR reactions prior to amplification as the only positive control sample. In this fashion >200 multiplex clinical PCR analyses of >4,000 clinical patient samples have been controlled simultaneously for PCR amplification and substrate specificity for 29 tested mutations without cross contamination. This clinically validated multiplex cystic fibrosis control can be modified readily for different test formats and provides a robust means to control for all mutations instead of rotating human genomic controls each with a fraction of the mutations. This approach allows scores of additional mutation controls from any gene loci to be added to the same mixture annually.     

Direct analysis of CYP21B genes in 21-hydroxylase deficiency using polymerase chain reaction amplification

Steroid 21-hydroxylase deficiency is the leading cause of impaired cortisol synthesis in congenital adrenal hyperplasia (CAH). We have studied the structure of the CYP21B gene in 30 unrelated CAH patients using the polymerase chain reaction (PCR) to differentiate the active CYP21B gene from its highly related CYP21A pseudogene. The PCR approach obviates the need to distinguish the CYP21A and CYP21B genes by restriction endonuclease digestion and electrophoresis before analysis with labeled probes. Furthermore, direct nucleotide sequence analysis of CYP21B genes is demonstrated on the PCR-amplified DNA. Gene deletion of CYP21B, gene conversion of the entire CYP21B gene to CYP21A, frame shift mutations in exon 3, an intron 2 mutation that causes abnormal RNA splicing, and a mutation leading to a stop codon in exon 8 appear to be the major abnormalities of the CYP21B gene in our patients. These mutations appear to account for 21-hydroxylase deficiency in 22 of 26 of our salt-wasting CAH patients.     

Comparison of Pre-Analytical FFPE Sample Preparation Methods and Their Impact on Massively Parallel Sequencing in Routine Diagnostics

Over the last years, massively parallel sequencing has rapidly evolved and has now transitioned into molecular pathology routine laboratories. It is an attractive platform for analysing multiple genes at the same time with very little input material. Therefore, the need for high quality DNA obtained from automated DNA extraction systems has increased, especially to those laboratories which are dealing with formalin-fixed paraffin-embedded (FFPE) material and high sample throughput. This study evaluated five automated FFPE DNA extraction systems as well as five DNA quantification systems using the three most common techniques, UV spectrophotometry, fluorescent dye-based quantification and quantitative PCR, on 26 FFPE tissue samples. Additionally, the effects on downstream applications were analysed to find the most suitable pre-analytical methods for massively parallel sequencing in routine diagnostics. The results revealed that the Maxwell 16 from Promega (Mannheim, Germany) seems to be the superior system for DNA extraction from FFPE material. The extracts had a 1.3–24.6-fold higher DNA concentration in comparison to the other extraction systems, a higher quality and were most suitable for downstream applications. The comparison of the five quantification methods showed intermethod variations but all methods could be used to estimate the right amount for PCR amplification and for massively parallel sequencing. Interestingly, the best results in massively parallel sequencing were obtained with a DNA input of 15 ng determined by the NanoDrop 2000c spectrophotometer (Thermo Fisher Scientific, Waltham, MA, USA). No difference could be detected in mutation analysis based on the results of the quantification methods. These findings emphasise, that it is particularly important to choose the most reliable and constant DNA extraction system, especially when using small biopsies and low elution volumes, and that all common DNA quantification techniques can be used for downstream applications like massively parallel sequencing.     

An efficient TILLING platform for cultivated tobacco

Targeting-induced local lesions in genomes(TILLING) is a powerful reverse-genetics tool that enables high-throughput screening of genomic variations in plants.Although TILLING has been developed for many diploid plants, the technology has been used in very few polyploid species due to their genomic complexity. Here, we established an efficient capillary electrophoresis-based TILLING platform for allotetraploid cultivated tobacco(Nicotiana tabacum L.) using an ethyl methanesulfonate(EMS)-mutagenized population of 1,536 individuals. We optimized the procedures for endonuclease preparation,leaf tissue sampling, DNA extraction, normalization,pooling, PCR amplification, heteroduplex formation, and capillary electrophoresis. In a test screen using seven target genes with eight PCR fragments, we obtained 118 mutants. The mutation density was estimated to be approximately one mutation per 106kb on average.Phenotypic analyses showed that mutations in two heavy metal transporter genes, HMA2S and HMA4T, led to reduced accumulation of cadmium and zinc, which was confirmed independently using CRISPR/Cas9 to generate knockout mutants. Our results demonstrate that this powerful TILLING platform(available at http://www.croptilling.org)can be used in tobacco to facilitate functional genomics applications.     

Detection of alcohol-tolerant hiochi bacteria by PCR.

We report a sensitive and rapid method for detection of hiochi bacteria by PCR. This method involves the electrophoresis of amplified DNA. Nucleotide sequences of the spacer region between 16S and 23S rRNA genes of 11 Lactobacillus strains were identified by analysis of PCR products. Five primers were designed by analysis of similarities among these sequences. A single cell of Lactobacillus casei subsp. casei could be detected when purified genomic DNA was used as the template. When various cell concentrations of L. casei subsp. casei were added to 50 ml of pasteurized sake and the cells were recovered, the detection limit was about one cell. No discrete band was observed in electrophoresis after PCR when human, Escherichia coli, mycoplasma, Acholeplasma, yeast, or mold DNA was used as the template.     

改进重叠延伸法引入DNA定点突变的新方法

目的：改进重叠延伸PCR法,实现一种引入DNA定点突变的准确简便方法。方法：通过应用不同的扩增酶和反应体系,以重叠延伸PCR的方法产生引入突变位点的DNA片断,然后再亚克隆到载体中。该文以人cyclin D1启动子的NF-κB位点（-39/-30）为例。结果：通过DNA测序证明定点突变成功引入。一次引入4个突变碱基。突变引入率为100%。