Genotyping and haplotyping of the dopamine D4 receptor gene by capillary electrophoresis

In this paper we report on simultaneous genotyping of adjacent polymorphisms (referred to as haplotyping) by combining double-tube allele-specific polymerase chain reaction, restriction fragment length polymorphism and capillary gel electrophoresis analysis of the resulting fragments. Direct molecular haplotyping is of particular importance in the case of double heterozygote samples, since in these instances the haplotype structure cannot be constructed based on genotype data. Our approach provided a powerful tool for coincidental genotype analysis of the 48 base pair (bp) variable number of tandem repeats of the third exon and haplotype investigation of the -616CG and -521CT single nucleotide polymorphisms of the dopamine D4 receptor (DRD4) gene. The linear polyacrylamide sieving matrix was optimized for the size range of the double-stranded DNA fragments of interest varying from 35 to 763 bp. We demonstrated that capillary gel electrophoresis in combination with laser induced fluorescence detection offers a sensitive and accurate tool for automated haplotyping in clinical settings.     

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.     

Rapid sizing of microsatellite alleles by gel electrophoresis on microfabricated channels: application to the D19S394 tetranucleotide repeat for cosegregation study of familial hypercholesterolemia.

This study evaluated the applicability of microchip electrophoresis to the sizing of microsatellites suitable to genetic, clinical and forensic applications. The evaluation was performed with the D19S394 tetranucleotide (AAAG) repeat characterized by a wide variation in the repeat number (1-17) and a short recombination distance from the low-density lipoprotein (LDL)-receptor gene that makes it suitable to cosegregation analysis of familial hypercholesterolemia (FH). The study was performed with 70 carriers of two LDL-receptor mutations common in northern Italy (i.e., the 4 bp insertion in exon 10 known as FH-Savona and the D200G missense mutation in the exon 4, known as FH-Padova 1) and 100 healthy controls. The polymerase chain reaction (PCR) amplification products prepared with a cosolvent PCR protocol and an antibody-protected polymerase were directly analyzed with an apparatus for high-voltage capillary electrophoresis on microchips and laser-induced fluorescence detection equipped with chips for the analysis of 25-500 bp dsDNA fragments. The test could not be extended to dinucleotide repeats due to the resolution characteristics of the available microchip. This novel approach was able to distinguish 17 microsatellite alleles varying from 0 to 17 repeats. Many of these alleles were quite rare, but the seven more abundant accounted for over the 70% of allele distribution in control population. The standard deviation in the sizing of the most abundant alleles ranged from +0.60 to +/- 0.75 bp. This indicated that the size attribution to a conventional allele using the +/- 1 bp range around it allowed a confidence limit above the 80 %. The sizing of D19S394 obtained this way allowed the cosegregation analysis with both the FH mutations tested. Therefore, this innovative approach to microsatellite sizing was much simpler, but equally effective as traditional capillary electrophoresis, at least with tetranucleotide repeats.     

Characterization of a highly variable short tandem repeat polymorphism at the D2S1242 locus

We report the evaluation of short tandem repeat (STR) locus D2S1242 (GDB ID G00-309-429) for forensic purposes, investigated by polymerase chain reaction (PCR) amplification and both native and denaturating polyacrylamide gel electrophoresis in 147 unrelated Austrians. No deviations from Hardy-Weinberg expectations were observed. The mean exclusion chance (MEC) was 0.669, the discriminating power (DP) was 0.947, and the observed heterozygosity rate was 0.856. An allelic ladder consisting of eight sequenced alleles (141-167 and 175 bp) was constructed. Sequence analysis revealed that the locus comprised two repeat motifs varying in number between alleles GAAA and GAAG. According to the number of tetranucleotide repeats the smallest allele was designated as 10 and the largest allele as 18.     

Analysis of five rare alleles at the STR loci D1S1656, D12S391, D13S317, Penta D,and D2S441

Short tandem repeat (STR) automatic typing technology is extensively used in forensic laboratories with commercial kits, in rare cases genotyping misinterpretations or mislabeling may occur due to unexpected rare alleles. This study refers to the investigation of several rare alleles observed from routine cases. Besides cross-kit verification with Goldeneye 25A (Beijing PeopleSpot Inc, China) and Huaxia platinum (Thermo Fisher Scientific, USA) kits, the next-generation sequencing technology by MiSeq FGx System (Illumina, USA) was applied to further validation. To solve the inconsistent outcomes reached by the above mentioned approaches at D2S441 locus, single gene amplification, gene cloning, and genetic sequencing was also performed. As a result, five rare alleles were detected. Two novel alleles of allele 3 at the D13S317 locus and allele 5 at the D2S441 locus were found; three previously reported alleles of allele 9 at D1S1656 locus, allele 19 at Penta D locus, and allele 28 at D12S391 locus in STRBase were initially supplemented with sequence information. We, therefore, propose that such uncommon observations with rare events should be carefully investigated and interpreted.     

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.     

Locus-specific brackets for reliable typing of Y-chromosome short tandem repeat markers

Short tandem repeat (STR) loci, widely used as genetic markers in disease diagnostic studies and human identity applications, are traditionally genotyped through comparison of allele sizes to a sequenced allelic ladder. Allelic ladders permit a floating bin allele calling method to be utilized, which enables reliable allele calling across laboratories, instrument platforms, and electrophoretic conditions. Precise sizing methods for STR allele calling involving fixed bins can also be used when a high degree of precision has been demonstrated within an instrument platform and a set of electrophoretic conditions. An alternative method for reliable genotyping of STR markers, locus-specific brackets (LSBs), is introduced here. LSBs are artificial alleles created through molecular biology manipulations to be shorter or longer than alleles commonly seen in populations under investigation. The size and repeat number of measured alleles are interpolated between the two LSB products that are mixed with the polymerase chain reaction-amplified STR alleles. The advantages and limitations of the LSB approach are described along with a concordance study between the LSB typing approach and other STR typing methods. Complete agreement was observed with 162 samples studied at 5 Y-chromosome loci.     

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.     

Detection of sequence variability of the collagen type IIalpha 1 3' variable number of tandem repeat

The variable number of tandem repeat (VNTR) 3' of the collagen type II (COL2A1) gene has been shown to be highly variable with a complex molecular structure. In a previous pilot experiment we observed discordance between methods to genotype this informative marker. To further investigate the extent and molecular nature of this discordance, we genotyped a random sample of 207 Caucasian individuals with two genotyping methods and sequenced new alleles. We compared single-strand (SS) analysis, which is based on detection of size differences between the different alleles, and heteroduplex analysis (HA), which is sensitive to both size and sequence differences. Overall, 26% of discordance between the two methods was detected. Approximately two thirds of this discordance was caused by subdivision of SS-alleles 13R1 and 14R2 into HA-alleles 4A + 4B and 3B + 3C, respectively. Sequence analysis of the COL2A1 VNTR alleles 4B and 3C showed that these alleles differed in sequence, but not in size, from already described SS-alleles, which explains why they escape detection by SS. The 4B allele is a frequent allele in the population (14%) and is, therefore, important to distinguish in association studies. We conclude that HA is a reliable method when the described optimized electrophoretic conditions are used. HA is a sensitive genotyping method to document allelic diversity at this locus, which can distinguish more alleles compared to the SS method.     

Direct haplotype detection of adjacent polymorphic sites in the regulatory region of the dopamine D4 receptor (DRD4) gene

A novel method of haplotype identification is discussed allowing simultaneous detection of two adjacent polymorphic sites, a single nucleotide polymorphism (SNP) and a length polymorphism within 1-2 kilobase distance. The method combines allele specific-amplification with high-throughput, automated ultrathin-layer gel electrophoresis analysis of fragment size polymorphism. A typical application is shown for genotyping the -521 C/T single nucleotide polymorphism and the 120 bp duplication in the 5"-upstream region of the dopamine D4 receptor (DRD4) gene. We have also demonstrated that the haplotypes of double heterozygotes for -521 C/T and for the 120 bp duplication can be clearly distinguished, that has only been possible previously by extensive pedigree analysis.     

Genotyping short tandem repeats using flow injection and electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry

Characterizing polymerase chain reaction (PCR) amplicons has been accomplished for the first time using flow injection analysis coupled to electrospray ionization mass spectrometry (ESI-MS). The PCR amplicons were amplified at the human tyrosine hydroxylase short tandem repeat locus from an individual homozygotic for the 9.3 allele. One product was amplified using Pfu polymerase and yielded a blunt-ended amplicon of 82 base-pairs (bp) in length. The second PCR product was amplified using Taq polymerase that resulted in an amplicon with cohesive termini of 82 bp plus either mono- or diadenylation. The two PCR amplicons were alternatively injected using a 0.5-microL loop at 2 microM for the Pfu amplicon and 1 microM for the Taq amplicon with a flow rate of 200 nL/min during data acquisition. Both PCR amplicons were accurately identified using mass measurements illustrating the compatibility of ESI-MS for genotyping short tandem repeat sequences and the potential for high-throughput genotyping of large PCR amplicons.     

Optimized suppression of adducts in polymerase chain reaction products for semi-quantitative SNP genotyping by liquid chromatography-mass spectrometry

While electrospray ionization mass spectrometry has shown great potential for the identification of genotypes in DNA sequences amplified by polymerase chain reaction (PCR), the quantitative determination of allele frequencies remains challenging because of the presence of cationic adducts in the mass spectra which severely impairs accuracy of quantitation. We report here on the elaboration of an optimized desalting protocol for ion-pair reversed-phase high-performance liquid chromatography-electrospray ionization mass spectrometry (ICEMS) of PCR amplicons which facilitates the genotyping of single nucleotide polymorphisms (SNPs). Chromatographic purification at temperatures between 50 and 70 degrees C using monolithic reversed-phase columns and acetonitrile gradients in aqueous, 20-30 mmol/l butyldimethylammonium bicarbonate enabled the mass spectrometric analysis of nucleic acid solutions containing up to 1.7 mol/l sodium chloride. A further improvement in removal of metal cations was achieved upon the addition of 5-10 mmol/l ethylenediaminetetraacetic acid (EDTA) to the sample solution prior to liquid chromatography. ICEMS was used for the semi-quantitative genotyping of SNPs amplified from the tetraploid genome of potato cultivars. Using a quadrupole ion trap mass spectrometer, allele frequencies were determined with an accuracy of 2-9% by measuring the relative intensities of the signals corresponding to the molecular mass of each of the alleles in the deconvoluted mass spectra. ICEMS results correlated well with those obtained by pyrosequencing, single nucleotide primer extension, and conventional dideoxy sequencing.     

A comparison of the effects of PCR inhibition in quantitative PCR and forensic STR analysis

In this paper we compare the effects of three representative PCR inhibitors using quantitative PCR (qPCR) and multiplex STR amplification in order to determine the effect of inhibitor concentration on allele dropout and to develop better ways to interpret forensic DNA data. We have used humic acid, collagen and calcium phosphate at different concentrations to evaluate the profiles of alleles inhibited in these amplifications. These data were correlated with previously obtained results from quantitative PCR including melt curve effects, efficiency changes and cycle threshold (Ct) values. Overall, the data show that there are two competing processes that result from PCR inhibition. The first process is a general loss of larger alleles. This appears to occur with all inhibitors. The second process is more sequence specific and occurs when the inhibitor binds DNA, altering the cycle threshold and the melt curve. This sequence-specific inhibition results in patterns of allele loss that occur in addition to the overall loss of larger alleles. The data demonstrate the applicability of utilizing real-time PCR results to predict the presence of certain types of PCR inhibition in STR analysis.     

Detection of errors in dinucleotide repeat typing by nondenaturing electrophoresis.

This study shows that consideration of minor bands (heteroduplex, shadow, and faint bands) associated with allele bands in nondenaturing polyacrylamide gel electrophoresis (PAGE) after polymerase chain reaction (PCR) is effective for detecting PCR processing errors that lead to mistyping of heterozygotes as homozygotes. Notably, we show that minor bands in native gels are highly effective for detecting allele dropout and preferential amplification in PCR amplification of dinucleotide repeats. These findings are based on an analysis of Mendelian inheritance patterns in families, and the reproduction of heterozygous band patterns by mixing homozygous DNAs before PCR, for a total of six (AC)n repeats located on human chromosome 11p15. To investigate the utility of our approach, a large population sample of 405 unrelated individuals was genotyped for each (AC)n repeat using minor bands as internal quality controls. Genotype frequencies at each of the six loci were in close agreement with Hardy-Weinberg proportions, which suggests that there were few genotyping errors. Our observations add to the evidence indicating that minor bands in native gels are of diagnostic value in the genotyping of dinucleotide repeats.     

Simultaneous analysis of multiple PCR amplicons enhances capillary SSCP discrimination of MHC alleles

Major histocompatibility complex (MHC) genotyping still remains one of the most challenging issues for evolutionary ecologists. To date, none of the proposed methods have proven to be perfect, and all provide both important pros and cons. Although denaturing capillary electrophoresis has become a popular alternative, allele identification commonly relies upon conformational polymorphisms of two single‐stranded DNA molecules at the most. Using the MHC class II (β chain, exon 2) of the black kite (Aves: Accipitridae) as our model system, we show that the simultaneous analysis of overlapping PCR amplicons from the same target region substantially enhances allele discrimination. To cover this aim, we designed a multiplex PCR capable to generate four differentially sized and labeled amplicons from the same allele. Informative peaks to assist allele calling then fourfold those generated by the analysis of single PCR amplicons. Our approach proved successful to differentiate all the alleles (N=13) isolated from eight unrelated birds at a single optimal run temperature and electrophoretic conditions. In particular, we emphasize that this approach may constitute a straightforward and cost‐effective alternative for the genotyping of single or duplicated MHC genes displaying low to moderate sets of divergent alleles.     

Lateral flow dipstick test for genotyping of 15 beta-globin gene (HBB) mutations with naked-eye detection

For definitive diagnosis of thalassemia carriers and patients, as well as for prenatal diagnosis, genotype analysis is of fundamental importance. We report a dry-reagent, lateral flow dipstick test that enables visual genotyping (detection by naked eye) of 15 mutations common in Mediterranean populations in the beta-globin gene (HBB). The method comprises 3 simple steps: (i) PCR amplification of a single 1896 bp segment of the beta globin gene flanking all 15 mutations; (ii) a multiplex (10-plex and/or 30-plex) primer extension reaction of the unpurified amplification product using allele-specific primers. Biotin is incorporated in the extended product; (iii) a dry-reagent multi-allele (10-plex) dipstick assay for visual detection of the primer extension reaction products within minutes. The total time required for PCR, primer extension reaction and the dipstick assay is ∼2 h. The method was evaluated by genotyping 45 DNA samples of known genotypes and 54 blind samples. The results were fully concordant with reference methods. The method is simple, rapid, and cost-effective. Detection by the dipstick assay does not require specialized instrumentation or highly qualified personnel. The proposed method could be a particularly useful tool in laboratories with limited resources and a basis for point-of-care diagnostics especially in combination with PCR amplification from whole blood.     

A multiplex SNP genotyping by allele‐specificspecific PCR based on stem‐loop and universal fluorescent primers of Chr1daxin mice

Single nucleotide polymorphisms (SNPs) are one of the most common markers in mammals. Rapid, accurate, and multiplex typing of SNPs is critical for subsequent biological and genetic research. In this study, we have developed a novel method for multiplex genotyping SNPs in mice. The method involves allele‐specific PCR amplification of genomic DNA with two stem‐loop primers accompanied by two different universal fluorescent primers. Blue and green fluorescent signals were conveniently detected on a DNA sequencer. We verified four SNPs of 65 mice based on the novel method, and it is well suited for multiplex genotyping as it requires only one reaction per sample in a single tube with multiplex PCR. The use of universal fluorescent primers greatly reduces the cost of designing different fluorescent probes for each SNP. Therefore, this method can be applied to many biological and genetic studies, such as multiple candidate gene testing, genome‐wide association study, pharmacogenetics, and medical diagnostics.     

Human Y-chromosome haplotyping by allele-specific polymerase chain reaction

We describe the application of allele-specific PCR (AS-PCR) for screening biallelic markers, including SNPs, within the nonrecombining region of the human Y-chromosome (NRY). The AS-PCR method is based on the concept that the perfectly annealed primer-template complex is more stable, and therefore, more efficiently amplified under the appropriate annealing temperature than the complex with a mismatched 3'-residue. Furthermore, a mismatched nucleotide at the primer's 3'-OH end provides for a poor extension substrate for Taq DNA polymerase, allowing for discrimination between the two alleles. This method has the dual advantage of amplification and detection of alleles in a single expeditious and inexpensive procedure. The amplification conditions of over 50 binary markers, mostly SNPs, that define the major Y-haplogroups as well as their derived lineages were optimized and are provided for the first time. In addition, artificial restriction sites were designed for those markers that are not selectively amplified by AS-PCR. Our results are consistent with allele designations derived from other techniques such as RFLP and direct sequencing of PCR products.     

Genotyping of simple sequence repeats--factors implicated in shadow band generation revisited

PCR amplification of microsatellite sequences generates, besides the main product corresponding to allele size, also additional, undesired products usually shorter by multiples of the repeated unit. These extra products known as shadow bands or stutter products may complicate genotyping. The mechanism by which these artifacts are formed is not well understood and so no effective remedy has been found to cope with these spurious products. In this study, using the DNA templates containing the CAG/CTG repeats flanked by gene-specific sequences and universal priming sites, we analyzed the effects of many PCR variables on the shadow band generation. The most important result was that at the decreased temperature of the denaturation step during PCR cycling the shadow bands were either not formed or were strongly suppressed. Several possible sources of this effect are discussed.     

Detection of cell-free fetal DNA in maternal plasma using two types of compound markers

With the discovery of circulating cell-free fetal DNA (cffDNA) in maternal plasma, noninvasive prenatal testing became possible. However, analysis of low-level cffDNA against high background maternal DNA remains complicated and challenging. To circumvent this limitation, selective amplification of cffDNA was used in this study. Two kinds of compound markers (namely DIP-STR and SNP-STR), both based on selective amplification, were used here for targeting fetal DNA. By designing two allele-specific forward primers for DIP-STR and SNP-STR, DNA fragments with different DIP/SNP alleles can be selectively amplified. When analyzing maternal plasma DNA, these markers can selectively target paternally inherited fetal alleles whose DIP/SNP allele was not shared with the mother. In this study, 21 families were studied with six DIP-STRs and 11 SNP-STRs. Fetal DNA was successfully detected across plasma samples for at least one marker. Detection rate varied between DIP-STR and SNP-STR markers, and DIP-STR outperforms SNP-STR. Fetal alleles obtained from maternal plasma were double confirmed by genotyping paternal genomic DNA and fetal genomic DNA from amniocentesis. This study demonstrated that selective amplification strategy can be used to target cffDNA in maternal plasma, which will be a promising method for noninvasive prenatal paternity testing.