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.     

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.     

AOTF-based multicolor fluorescence detection for short tandem repeat (STR) analysis in an electrophoretic microdevice

An acousto-optic tunable filter (AOTF) has been used to perform multicolor fluorescence detection for four and five-color short tandem repeat (STR) analysis on glass microchips. Matrix files were initially generated by collecting and comparing the laser-induced fluorescence emission of the labels specific to a particular STR kit, and raw data was processed to remove spectral overlap. The AmpFlSTR kits used in this work include Profiler Plus and COfiler, which are four-color kits used in tandem to address the core STR loci, as well as the five-color Identifiler kit, which contains each of the loci. In contrast to previous reports on multicolor detection for STR analysis on microchips, this detection system is characterized by a single filter and detector, and reports the first five-color genotyping application on-chip. This capability matches the portability and reduced scale of the microchip with the state-of-the-art in multicolor STR analysis kits.     

CEPH family 1362 STR database: An online resource for characterization of PCR products using electrospray ionization mass spectrometry

An online database has been established in order to validate electrospray ionization mass spectrometry (ESI-MS) for genotyping and to publicize the procedures developed in our laboratory for the characterization of PCR products by ESI-MS. Genotypes derived from short tandem repeat (STR) loci that were obtained using ESI Fourier transform ion cyclotron resonance mass spectrometry (FTICR-MS) have been posted for fifteen members of the CEPH family 1362 pedigree. The website provides specific information such as PCR parameters, PCR product cleanup approaches, and ESI solution compositions to enable other laboratories to reproduce our data. Links are provided to related websites in an effort to integrate information regarding the CEPH family, STR genotyping, and mass spectrometry. The database, currently available at http://www.people.vcu.edu/ -dcmuddim/genotype/ will be routinely updated with genotypes from additional STR loci including PCR parameters as well as PCR cleanup strategies as further developments are completed.     

Probing possible left- and right-handed poly(dinucleotide) helical conformations from (n–h) plots. models for polysequential nucleotides

Introducing the concept of the “dinucleotide” as the helical repeat, theoretical attempts have been made to determine possible single and double stranded helical structures by using helical parameter calculations and model building investigations. By virtue of its flexible framework, the dinucleotide repeat offers a much greater scope of finding new secondary structural forms for nucleic acids. Considering only those conformations which show tendency for at least partial base overlap as does the dinucleotide helical repeat, it has been possible to predict poly(dinucleotide) helical models in which successive phosphodiesters as well as nucleotide conformations alternate. More important, the recently found left-handed Z-type polynucleotide helix is characterized rather uniquely on the helical parameter plot. The results further suggest the possibility of other Z-type helices obtainable by alternative conformations for the exocyclic C4'–C5' bond and sugar pucker. Near neighbor long range conformational correlations between the dinucleotide repeat and the phosphodiester linking them have been established similar to poly(mononucleotide) helices. Need for considering higher repeats such as trinucleotide has been suggested to obtain models for looped out helical conformations.     

De novo mutations in sporadic deletional Duchenne muscular dystrophy (DMD) cases

Dinucleotide repeat polymorphism based genetic analysis is a powerful approach to gain insight into rare genetic events like germline mosaicism and de novo mutations. The loss of heterozygosity of polymorphic dinucleotide loci at "deletional hotspot" of dystrophin gene can provide direct evidence of carrier status in female relatives of affected DMD patients with overlapped exonic deletions. We have used 4 STR loci of the central deletional hotspot of the dystrophin gene for genetic analysis in sporadic unrelated DMD families. Twenty-nine mothers of sporadic deletional cases were analysed and their carrier status was determined. Eighteen of them showed heterozygosity in the deleted loci suggesting the occurrence of de novo mutations. In 9 cases, the carrier status was indeterminate while 2 showed germline mosaicism. Our observations reiterated the importance of STR analysis in determining the status of mothers of sporadic deletional DMD cases in order to provide proper genetic counselling.     

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.     

Multiple genotyping based on multiplex PCR and microarray

The genetic variability has obtained more and more attention in the process of diagnosis and treatment of tumors.Herein,we have described a multiple genotyping method based on magnetic enrichmentmultiplex PCR (MEM-PCR) and microarray technology.Monodisperse magnetic beads were fabricated and modified with streptavidin.Four loci on two genes (M235T and A-6G loci on AGT gene,A1298C and C677T loci on MTHFR gene) were selected to study single nucleotide polymorphisms (SNP).Target sequences of these SNP loci were amplified using Cy3-labeled primers through multiplex PCR in one tube after the templates were enriched and purified by functional magnetic beads (MB).Four pairs of NH₂-labeled probes,corresponding to each locus,were fixed on CHO-modified glass slide by covalent binding.Hybridization between target sequences and probes was performed under suitable conditions.The spotting locations on microarray and the ratio of fluorescence intensity,produced by different loci,were used to distinguish the SNP genotypes.Finally,three of gastric cancer samples were collected and genotyping analysis for these four SNP loci was carried out successfully simultaneously by this method.     

Separation mixed semen of two individuals using magnetic beads coupled ABH blood group antibody

In sexual assault cases, one of the most common samples collected is a mixed semen stain, which is often found on the vagina, female underwear, or bed sheets. However, it is usually difficult to identify the perpetrator based on this sample alone. One technique that has been developed to address this issue is magnetic bead-based separation. This method involves using modified magnetic microspheres to capture and enrich specific target cells, in this case, sperm cells. In this study, we utilized magnetic beads coupled with ABH blood group antibody to isolate sperm cells from an individual of a single ABO blood type. Subsequently, polymerase chain reaction amplification and capillary electrophoresis were employed to perform the genotyping the short tandem repeat (STR) loci. This approach allows for the identification of different individuals in a mixed seminal stain sample from two individuals, by first separating sperm cells based on ABH antigen differences and subsequently utilizing autosomal STR typing on the enriched single blood group cells.     

Point Mutation Genotyping Based on Melting-Point Difference without Fluorescent Probes

Fluorescent method is a powerful tool for genotyping point mutations. Current existing methods usually need cost labeled fluorescent probes, which causes great limitation to their applications in clinic. Here, a fidelity method for genotyping point mutations has been developed based on melting‐point difference without labeled fluorescent probes. The method employs ligase to ligate two specific probes to produce a high melting temperature. The homozygotes and heterozygotes are scored accurately by obvious melting‐point difference among genotypes. This method would provide an accurate and economical‐cost tool for point mutation genotyping.     

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.     

Rapid and sensitive genotyping of dopamine D4 receptor tandem repeats by automated ultrathin-layer gel electrophoresis

Prior studies have revealed possible association between the presence of a seven repeat of the 48 bp variable number tandem repeat polymorphism of the human dopamine D4 receptor gene (DRD4) and some normal and pathological human traits, such as novelty seeking, hyperactivity disorders, and substance abuse. Some reports supported this finding whereas others did not. Incorrect genotyping could be one of the reasons for these controversial results, and might originate from preferential amplification of shorter polymerase chain reaction (PCR) products, resulting in the so-called allele dropout. In this paper we optimized the conditions for simultaneous amplification of shorter and longer amplicons of the 48 bp repeat region of the DRD4 gene in order to avoid the loss of the longer allele and consequent incorrect genotyping, using very low DNA template concentrations and partial replacement of 2'-deoxyguanosine-5'-triphosphate (dGTP) by 2'-deoxyinosine-5'-triphosphate (dITP). The optimized PCR method in combination with high throughput automated ultrathin-layer gel electrophoresis was suitable for rapid genotyping from less than a nanogram DNA using noninvasive sampling (buccal epithelial cells). All detected genotypes are presented, including such rear heterozygotes as the 2 x and 8 x 48 bp repeats in the same sample, showing the reliability of our novel detection method of longer alleles in the presence of shorter alleles.     

Genetic profile characterization and population study of 21 autosomal STR in Chinese Kazak ethnic minority group

Short tandem repeat loci have been recognized as useful tools in the routine forensic application and in recent decades, more and more new short tandem repeat (STR) loci have been constantly discovered, studied, and applied in forensic caseworks. In this study, we investigated the genetic polymorphisms of 21 STR loci in the Kazak ethnic minority as well as the genetic relationships between the Kazak ethnic minority and other populations. Allelic frequencies of 21 STR loci were obtained from 114 unrelated healthy Kazak individuals in the Ili Kazak Autonomous Prefecture, Xinjiang Uigur Autonomous Region of China. We observed a total of 159 alleles in the group with the allelic diversity values ranging from 0.0044 to 0.5088. The highest polymorphism was found at D19S433 locus and the lowest was found at D1S1627. Statistical analysis of the generated data indicated no deviation from Hardy–Weinberg equilibriums at all 21 STR loci. In order to estimate the population differentiation, allelic frequencies of all STR loci of the Kazak were compared with those of other neighboring populations using analysis of molecular variance method. Statistically significant differences were found between the studied population and other populations at 2–7 STR loci. A neighbor‐joining tree was constructed based on allelic frequencies of the 21 STR loci and phylogenetic analysis indicates that the Kazak has a close genetic relationship with the Uigur ethnic group. The present results may provide useful information for forensic sciences and population genetics studies, and can also increase our understanding of the genetic background of this group. The present findings showed that all the 21 STR loci are highly genetically polymorphic in the Kazak group, which provided valuable population genetic data for the genetic information study, forensic human individual identification, and paternity tests.     

High throughput screening of genetic polymorphisms by matrix-assisted laser desorption ionization time-of-flight mass spectrometry

In the post genomic era, the screening of many different genetic polymorphisms in large populations represents a major goal that will facilitate the understanding of individual genetic variability in the development of multi factor diseases and in drug response and toxicities. The increasing interest in these pathogenetic and pharmacogenomic studies by both academic and pharmaceutical industry researchers has increased the demand for broad genome association studies. This demand has produced a boom in the development of new and robust high throughput screening methods for genotype analysis. Matrix-assisted laser-desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS) represents an emerging and powerful technique for DNA analysis because of its high speed, accuracy, no label requirement, and cost-effectiveness. So far, many MALDI-TOF MS approaches have been developed for rapid screening of single nucleotide polymorphisms (SNPs), variable sequences repeat, epigenotype analysis, quantitative allele studies, and for the discovery of new genetic polymorphisms. The more established methods are based on single base primer extension and minisequencing implemented with new chemical features to overcome the limitations associated with DNA analysis using MALDI-TOF MS. These new promising methods of genotyping include both photochemical and other different chemical and enzyme cleavage strategies that facilitate sample automation and MS analysis for both real-time genotyping and resequencing screening. In this review, we analyze and discuss in depth the advantages and the limitations of the more recent developments in MALDI-TOF MS analysis for large-scale genomic studies applications.     

Haplotype studies support slippage as the mechanism of germline mutations in short tandem repeats

Germline mutations of human short tandem repeat (STR) loci are expansions or contractions of repeat arrays which are not well understood in terms of the mechanism(s) underlying such mutations. Although polymerase slippage is generally accepted as a mechanism capable to explain most features of such mutations, it is still possible that unequal crossing over plays some role in those events, as most studies in humans could not exclude unequal crossing over (UCO). Crossing over can be studied by analyzing haplotypes using flanking markers. To check for UCO in mutations, we have analyzed 150 paternity cases for which more than the usual trio (mother, child, and father) were available for testing by analyzing 16 STR loci. In a total of 4900 parent-child allele transfers four mutations were observed at different loci (D8S1179, D18S51, D21S11, and SE33/ACTBP2). To identify the mutated allele and to check for UCO, we typed at least four informative loci flanking the mutated locus and used the pedigree data to establish haplotypes. By doing so we were able to exclude UCO in each case. Moreover, we were able to identify the mutations as one-repeat contractions/expansions. Our data thus support slippage as the mechanism of germline mutations in STRs.     

Cost-effective interrogation of single nucleotide polymorphisms using the mismatch amplification mutation assay and capillary electrophoresis

The ability to characterize SNPs is an important aspect of many clinical diagnostic, genetic and evolutionary studies. Here, we designed a multiplexed SNP genotyping method to survey a large number of phylogenetically informative SNPs within the genome of the bacterium Bacillus anthracis. This novel method, CE universal tail mismatch amplification mutation assay (CUMA), allows for PCR multiplexing and automatic scoring of SNP genotypes, thus providing a rapid, economical and higher throughput alternative to more expensive SNP genotyping techniques. CUMA delivered accurate B. anthracis SNP genotyping results and, when multiplexed, saved reagent costs by more than 80% compared with TaqMan real-time PCR. When real-time PCR technology and instrumentation is unavailable or the reagents are cost-prohibitive, CUMA is a powerful alternative for SNP genotyping.     

Applications of MALDI‐TOF MS to large‐scale human mtDNA population‐based studies

Analysis of the mitochondrial DNA variation in populations is commonly carried out in many fields of biomedical research. We propose the analysis of mitochondrial DNA coding region SNP (mtSNP) variation to a high level of phylogenetic resolution based on MALDI‐TOF MS. The African phylogeny has been chosen to test the applicability of the technique but any other part of the worldwide phylogeny (or any other mtSNP panel) could be equally suitable for MALDI‐TOF MS genotyping. SNP selection thus aimed to fully cover all the mtSNPs defining major and minor branches of the known African tree, including, macro‐haplogroup L, and haplogroups M1, and U6. A total of 230 mtSNPs were finally selected. We used tests samples collected from two different African locations, namely, Mozambique and Chad Basin. Different internal genotyping controls and other indirect approaches (e.g. phylogenetic checking coupled with automatic sequencing) were used in order to evaluate the reproducibility of the technique, which resulted to be 100% using samples previously subjected to whole genome amplification. The advantages of the MALDI‐TOF MS are also discussed in comparison with other popular methods such as minisequencing, highlighting its high‐throughput nature, which is particularly suitable for case–control medical studies, forensic databasing or population and anthropological studies.     

Ag nanoclusters as probes for turn-on fluorescence recognition of TpG dinucleotide with a high selectivity

CpG dinucleotide in DNA has a great tendency to mutate to TpG dinucleotide and this transition can cause some serious diseases. In this work, fluorescent Ag nanoclusters (Ag NCs) were employed as useful inorganic fluorophores for the potential of selectively discriminating TpG dinucleotide from CpG dinucleotide. Opposite the base Y of interest in YpG dinucleotide (Y = C or T), a bulge site was introduced so as to make the base Y to be unpaired and ready for Ag⁺ binding. Such that the unpaired Y and context base pairs can provide a specific space suitable for creating fluorescent Ag NCs. We found that in comparison with CpG dinucleotide, TpG dinucleotide is much more efficient in growing fluorescent Ag NCs. Therefore, mutation of CpG dinucleotide to TpG can be identified by a turn-on fluorescence response and a high selectivity. More interestingly, Ag NCs exhibit a better performance in the TpG recognition over the other dinucleotides (Y = A and G) than the previously used organic fluorophores. Additionally, the effectiveness of the bulge site design in discriminating these dinucleotides was evidenced by control DNAs having the abasic site structure. We expect that a practical method for TpG dinucleotide recognition with a high selectivity can be developed using the bulge site-grown fluorescent Ag NCs as novel probes.     

Development of a novel forensic STR multiplex for ancestry analysis and extended identity testing

There is growing interest in developing additional DNA typing techniques to provide better investigative leads in forensic analysis. These include inference of genetic ancestry and prediction of common physical characteristics of DNA donors. To date, forensic ancestry analysis has centered on population‐divergent SNPs but these binary loci cannot reliably detect DNA mixtures, common in forensic samples. Furthermore, STR genotypes, forming the principal DNA profiling system, are not routinely combined with forensic SNPs to strengthen frequency data available for ancestry inference. We report development of a 12‐STR multiplex composed of ancestry informative marker STRs (AIM‐STRs) selected from 434 tetranucleotide repeat loci. We adapted our online Bayesian classifier for AIM‐SNPs: Snipper, to handle multiallele STR data using frequency‐based training sets. We assessed the ability of the 12‐plex AIM‐STRs to differentiate CEPH Human Genome Diversity Panel populations, plus their informativeness combined with established forensic STRs and AIM‐SNPs. We found combining STRs and SNPs improves the success rate of ancestry assignments while providing a reliable mixture detection system lacking from SNP analysis alone. As the 12 STRs generally show a broad range of alleles in all populations, they provide highly informative supplementary STRs for extended relationship testing and identification of missing persons with incomplete reference pedigrees. Lastly, mixed marker approaches (combining STRs with binary loci) for simple ancestry inference tests beyond forensic analysis bring advantages and we discuss the genotyping options available.     

Fluorescence polarization for single nucleotide polymorphism genotyping

Single nucleotide polymorphisms (SNPs) are the most abundant variations in the human genome and have become the primary markers for genetic studies for mapping and identifying susceptible genes for complex diseases. Methods that genotype SNPs quickly and economically are of high values for these studies because they require a large amount of genotyping. Fluorescence polarization (FP) is a robust technique that can detect products without separation and purification and it has been applied for SNP genotyping. In this article the applications of FP in SNP genotyping are reviewed and one of the methods, the FP-TDI assay, is discussed in details. It is hoped that readers could get useful information for the applications of FP in SNP genotyping and some insights of the FP-TDI assay.