Haplotyping by capillary electrophoresis

The investigation of the genetic background and phenotype structures of complex diseases, such as cardiovascular or psychiatric disorders and tumors, is one of the most scrutinized fields of the post genomic era. Besides the multiplex analysis of genetic markers and polymorphisms throughout the whole genome, more and more attention is focused on the interaction between the etiological factors of these traits. Haplotype determination, rather than multiplex genotyping seems to be one of the first building blocks of this endeavor. This review focuses on the importance and theoretical background of haplotyping, and summarizes the recent examples of novel and emerging haplotyping techniques by capillary gel electrophoresis based DNA fragment analysis, a powerful tool for the examination of the inheritance of complex traits.     

Analysis of dopamine D4 receptor gene polymorphism using microchip electrophoresis

A microfabricated electrophoresis device was used for rapid polymerase chain reaction product analysis in genotyping the dopamine D4 receptor gene (DRD4) 48 base pairs repeat polymorphism. An allelic ladder, prepared from homozygous individuals, was used as internal standard during the microchip electrophoresis based analysis. Comparison of this novel separation method with the conventional slab gel and previously reported ultra-thin-layer techniques confirmed the reliability of this new method. Genotyping of 332 healthy Hungarian individuals gave the following allele frequencies: two-repeat: 0.089; three-repeat: 0.026; four-repeat: 0.674; five-repeat: 0.011; six-repeat: 0.002; seven-repeat: 0.189; eight-repeat: 0.011. The genotype frequencies obtained showed no deviation from the Hardy-Weinberg equilibrium (p>0.903), further underlying the reliability of this new genotyping technique.     

Validation of a tentative microsatellite marker for the dopamine D4 receptor gene by capillary gel electrophoresis

Two to four-basepair-short tandem repeats (i.e. microsatellites) are broadly utilized as genetic markers for mapping disease loci in whole genome search analyses. Based on their close vicinity on chromosome 11, the D11S1984 microsatellite was anticipated as a tentative marker for the dopamine D4 receptor gene. A capillary gel electrophoresis based genotype analysis method and an in-house made computational tool was developed for the analysis of the D11S1984 microsatellite marker to examine a healthy Hungarian population of n=106. The data obtained did not suggest significant linkage between the D11S1984 marker and the DRD4 gene.     

High-throughput genotyping of repeat polymorphism in the regulatory region of serotonin transporter gene by gel microchip electrophoresis.

Large-scale genotyping of the repeat polymorphism in the regulatory region of the serotonin transporter gene (5-HTTLPR) was attempted by polymerase chain reaction (PCR) amplification followed by gel microchip electrophoresis analysis. The multilane (96) format of the gel microchip system allowed parallel separation of a large number of samples. The separation and visualization of the PCR amplicons from either the 5-HTTLPR short allele (number of repeats are 14) or the 5-HTTLPR long form (16 repeats) was completed in a few minutes. Genotyping of healthy Caucasian individuals showed that the short allele had a somewhat lower frequency (0.42) than the long form (0.58), and the genotype frequencies fulfilled the criteria of the Hardy-Weinberg equilibrium (chi = 0.012, p = 0.994). Based on these results, gel microchip electrophoresis system proved to be a powerful tool for high throughput genotyping of repeat polymorphism.     

Rapid genotyping of factor V Leiden mutation using single-tube bidirectional allele-specific amplification and automated ultrathin-layer agarose gel electrophoresis

We report a novel, high-throughput genotyping method by single nucleotide polymorphism (SNP) analysis using bidirectional allele-specific amplification with polymerase chain reaction (PCR) in a single-step/single-tube format. Blood coagulation factor V G1691A (also referred to as Leiden) mutation was chosen as a model system for SNP detection, as this is one of the most common inherited risk factors of thrombosis, effecting 2-5% of the human population. The rationale of our method is the production of allele-specific PCR fragments, different in size, which was achieved by bidirectional amplification, starting from the position of the mutation. Thus, both homozygosity and heterozygosity were readily identified from a single reaction by simply determining the sizes of the resulting PCR products. The advantage of our assay, compared to other single-tube systems, is that this method did not require the use of pre-PCR labeled (fluorophore) primers or probes. Preferential production of the allele-specific products was achieved by a hot-start, time release PCR system. Specificity was increased by introducing a mismatch in the 3'-antepenultimate position of the allele-specific primers. This method made possible the large-scale screening for the factor V Leiden mutation using single-tube PCR followed by automated ultrathin-layer agarose gel electrophoresis, with real-time detection of the "in migratio" ethidium-bromide-labeled fragments.     

Genotyping the -521C/T functional polymorphism in the promoter region of dopamine D4 receptor (DRD4) gene

The -521C/Tsingle nucleotide polymorphism (SNP) in the promoter region of the dopamine D4 receptor gene (DRD4) has recently been detected in oriental (Japanese) individuals and related to novelty seeking and schizophrenia. Here, we report the analysis of the -521C/T polymorphism in a Caucasian (Hungarian) population using two independent genotyping methods. The polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) procedure utilized the Fspl restriction site around the -521 position. An additional, nonpolymorphic cleavage site was also included into the amplified region to serve as an internal standard for verifying the completion of the digestion. As another independent method, a tetraprimer system for single-tube allele-specific PCR (SAS-PCR) was developed to generate -521C and -521T specific PCR products with different fragment sizes. Consequently, genotyping with SAS-PCR is based on the gel-electrophoretic separation of the allele-specific double-stranded DNA (dsDNA) fragments. 119 healthy Hungarian individuals were genotyped for -521C/T polymorphism of the dopamine D4 promoter region, using both methods. Similar allele frequencies were found (-521C allele: 0.43; -521T allele: 0.57) as reported earlier for the Japanese population.     

Structure-Based Design of Covalent Siah Inhibitors

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Membrane-mediated ultrafast restriction digestion and subsequent rapid gel microchip electrophoresis of DNA

Ultrafast, membrane-mediated restriction digestion of DNA molecules followed by rapid gel microchip electrophoresis of the resulting fragments is described. Combination of restriction endonuclease digestion on small pore-size microfibrous membranes with sample loading and electrophoresis analysis in a multilane (up to 96) format resulted in very fast restriction digest based microscale DNA analysis. Complete digestion of several nanogram target DNA was accomplished on the microporous membrane at room temperature just in a few minutes with a single or a combination of various restriction enzymes, using only submicroliter quantities of samples and reagents. The reaction mixture containing membrane also served as sample loading device for the subsequent gel microchip electrophoresis based analysis. This work establishes methods for high-speed, high-throughput DNA analysis, featuring extremely low sample and reagent consumption, and fast restriction digestion in combination with sample loading and rapid gel microchip analysis of the resulting fragments. The entire restriction digestion, sample loading and electrophoresis analysis process required less than 20 min.     

Haplotyping of putative microRNA-binding sites in the SNAP-25 gene

Synaptosomal-associated protein 25 (SNAP-25) plays a crucial role in exocitosis. Single nucleotide polymorphisms (rs3746544 and rs1051312) in the 3' un-translated region of the SNAP-25 gene have been described to be in association with attention-deficit hyperactivity disorder. As the disease affects millions of children world-wide, understanding the genetic background of attention-deficit hyperactivity disorder is of crucial importance. Efficient and reliable PCR-RFLP protocols were elaborated for the genotyping of the rs3746544 and rs1051312 SNPs employing a high-throughput capillary electrophoresis method for fragment analysis. A novel real-time PCR-based technique was used applying sequence specific TaqMan probes to haplotype the two SNPs, and the G-C haplotype could not be detected in a large Caucasian population (N=1376). These findings have been confirmed by molecular biology tools as well as by the PHASE Bayesian computational approach. In silico analyses have suggested that the two SNPs might alter microRNA binding and thus have an effect on SNAP-25 production. We have demonstrated that this biological information can be revealed only by direct haplotype analysis emphasizing the importance of our novel molecular haplotye analysis protocol. Results of the study of the two SNPs might shed light on the association of SNAP-25 variants and pathological phenotypes at the molecular level.