We have enhanced the polymerase chain reaction (PCR) such that specific DNA sequences can be detected without opening the reaction tube. This enhancement requires the addition of ethidium bromide (EtBr) to a PCR. Since the fluorescence of EtBr increases in the presence of double-stranded (ds) DNA an increase in fluorescence in such a PCR indicates a positive amplification, which can be easily monitored externally. In fact, amplification can be continuously monitored in order to follow its progress. The ability to simultaneously amplify specific DNA sequences and detect the product of the amplification both simplifies and improves PCR and may facilitate its automation and more widespread use in the clinic or in other situations requiring high sample throughput.
The analysis of DNA for the presence of particular mutations or polymorphisms can be readily accomplished by differential hybridization with sequence-specific oligonucleotide probes. The in vitro DNA amplification technique, the polymerase chain reaction (PCR), has facilitated the use of these probes by greatly increasing the number of copies of target DNA in the sample prior to hybridization. In a conventional assay with immobilized PCR product and labeled oligonucleotide probes, each probe requires a separate hybridization. Here we describe a method by which one can simultaneously screen a sample for all known allelic variants at an amplified locus. In this format, the oligonucleotides are given homopolymer tails with terminal deoxyribonucleotidyltransferase, spotted onto a nylon membrane, and covalently bound by UV irradiation. Due to their long length, the tails are preferentially bound to the nylon, leaving the oligonucleotide probe free to hybridize. The target segment of the DNA sample to be tested is PCR-amplified with biotinylated primers and then hybridized to the membrane containing the immobilized oligonucleotides under stringent conditions. Hybridization is detected nonradioactively by binding of streptavidin-horseradish peroxidase to the biotinylated DNA, followed by a simple colorimetric reaction. This technique has been applied to HLA-DQA genotyping (six types) and to the detection of Mediterranean (3-thalassemia mutations (nine alleles).Differential hybridization with sequence-specific oligonucleotide probes has become a widely used technique for the detection of genetic mutations and polymorphisms (1)(2)(3)(4)(5). When hybridized under the appropriate conditions, these synthetic DNA probes (usually 15-20 bases in length) will anneal to their complementary target sequences in the sample DNA only if they are perfectly matched. In most cases, the destabilizing effect ofa single base-pair mismatch is sufficient to prevent the formation of a stable probe-target duplex (6). With an appropriate selection of oligonucleotide probes, the relevant genetic content of a DNA sample can be completely described.This very powerful method of DNA analysis has been greatly simplified by the in vitro DNA-amplification technique, the polymerase chain reaction (PCR) (7-9). The PCR can selectively increase the number of copies of a particular DNA segment in a sample by many orders of magnitude. As a result ofthis 106-to 108-fold amplification, more convenient assays and nonradioactive detection methods have become possible (10)(11)(12). These PCR-based assays are usually done by amplifying the target segment in the sample to be tested, fixing the amplified DNA onto a series of nylon membranes, and hybridizing each membrane with one of the labeled oligonucleotide probes under stringent hybridization conditions. However, each probe must still be individually hybridized to the amplified DNA and the process can easily become difficult in a system where many different mutations or polymorphisms occur.One approach t...
We present a genotyping method for simultaneously scoring 116,204 SNPs using oligonucleotide arrays. At call rates >99%, reproducibility is >99.97% and accuracy, as measured by inheritance in trios and concordance with the HapMap Project, is >99.7%. Average intermarker distance is 23.6 kb, and 92% of the genome is within 100 kb of a SNP marker. Average heterozygosity is 0.30, with 105,511 SNPs having minor allele frequencies >5%.
The PCR amplification of tetranucleotide short tandem repeat (STR) loci typically produces a minor product band 4 bp shorter than the corresponding main allele band; this is referred to as the stutter band. Sequence analysis of the main and stutter bands for two sample alleles of the STR locus vWA reveals that the stutter band lacks one repeat unit relative to the main allele. Sequencing results also indicate that the number and location of the different 4 bp repeat units vary between samples containing a typical verses low proportion of stutter product. The results also suggest that the proportion of stutter product relative to the main allele increases as the number of uninterrupted core repeat units increases. The sequence analysis and results obtained using various DNA polymerases appear to support the slipped strand displacement model as a potential explanation for how these stutter products are generated.
The analysis of single nucleotide polymorphisms (SNPs) is increasingly utilizedto investigate the genetic causes of complex human diseases. Here we present a high-throughput genotyping platform that uses a one-primer assay to genotype over 10,000 SNPs per individual on a single oligonucleotide array. This approach uses restriction digestion to fractionate the genome, followed by amplification of a specific fractionated subset of the genome. The resulting reduction in genome complexity enables allele-specific hybridization to the array. The selection of SNPs was primarily determined by computer-predicted lengths of restriction fragments containing the SNPs, andwas further driven by strict empirical measurements of accuracy, reproducibility, andaverage call rate, which we estimate to be >9.5%, >99.9%, and>95%, respectively. With average heterozygosity of 0.38 andgenome scan resolution of 0.31 cM, the SNP array is a viable alternative to panels of microsatellites (STRs). As a demonstration of the utility of the genotyping platform in whole-genome scans, we have replicated and refined a linkage region on chromosome 2p for chronic mucocutaneous candidiasis and thyroid disease, previously identified using a panel of microsatellite (STR) markers
The preferential PCR amplification of one allele relative to another in a heterozygous sample could result in an incorrect or ambiguous genetic typing of that sample. There are several mechanisms that could potentially lead to such preferential PCR amplification. First, preferential amplification can result from significant GC% differences be-
A simple, rapid, and precise method of typing HLA class II polymorphism would be valuable in the areas of disease susceptibility, tissue transplantation, individual identification and anthropological genetics. Here we describe a method of analysing class II sequence polymorphism based on polymerase chain reaction (PCR) amplification and hybridization with oligonucleotide probes. One valuable property of sequence-based HLA typing strategies, like oligonucleotide probe hybridization, is that they reveal how and where two alleles differ, not simply that they can be operationally distinguished. The nature and location of HLA polymorphisms appears to be critical in disease association studies and are likely to be important in tissue typing for transplantation. New alleles at the DRB1, DPB1 and DQB1 loci are likely to be identified as this technology is applied to more and more samples, particularly in non-Caucasian ethnic groups. A new allele is uncovered as an unusual pattern of probe binding and then confirmed by sequencing. This pattern is observed because class II polymorphism is localized to specific regions and virtually all 'new' alleles have polymorphisms in the region of probe binding. Obviously, any new allele with a new polymorphic sequence in a region for which typing probes are not available would not be revealed by oligonucleotide typing. With the PCR primers and probes described here, 7 DQA1 alleles, 15 DQB1 alleles, 18 DPB1 alleles, and 32 DRB1 alleles are distinguished. Additional primers and/or probes can, of course, increase the allelic discrimination of oligonucleotide dot blot typing. These horseradish peroxidase (HRP)-labelled oligonucleotide probes are stable (greater than 2 years when stored at 4 degrees C) and the typing system is simple and robust. Over 500 samples from the CEPH pedigrees (unpublished data; A. B. Begovich, et al., manuscript in preparation) and greater than 1000 unrelated samples have been typed by this procedure. Although this dot blot/oligonucleotide hybridization procedure is a powerful and precise method of HLA class II typing, the complexity of the procedure increases as the number of probes required for analysis increases. The reverse dot blot method, based on an array of immobilized probes, allows the typing of individual samples in one single hybridization reaction. In this approach, a panel of unlabelled oligonucleotides are immobilized to a nylon membrane. The PCR product is labelled during the amplification reaction by using biotinylated primers and hybridized to the membrane. The presence of bound PCR product specifically hybridized to a given probe is detected using streptavidin-HRP conjugates and either chromogenic or chemiluminescent substrates.(ABSTRACT TRUNCATED AT 400 WORDS)
Automated fluorescence analysis of polymerase chain reaction (PCR)-amplified short tandem repeat (STR) systems by capillary electrophoresis (CE) is becoming an established tool both in forensic casework and in the implementation of both state and national convicted offender DNA databases. A new capillary electrophoresis instrument, the ABI Prism 310 Genetic Analyzer, along with the Performance Optimized Polymer 4 (POP-4) provides an automated and precise method for simultaneously analyzing ten fluorescently labeled STR loci from a single PCR amplification kit, which provides a power of discrimination of approximately one in five billion from a single PCR amplification. Data are presented on sizing precision, sizing accuracy, and resolution for the STR loci in the AmpFlSTR Profiler kit. Sizing accuracy is highly dependent on the electrophoresis system, and therefore the reporting of alleles based on the nucleotide size obtained from an electrophoresis system is not recommended for forensic work. The precision of the 310 capillary electrophoresis system, coupled with software developed for automated genotyping of alleles based on the use of an allelic ladder, allows for accurate genotyping of STR loci. Sizing precision of < or = 0.16 nucleotide standard deviation was obtained with this system, thus allowing for accurate genotyping of length variants that differ in length by a single nucleotide.
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