Genotyping and haplotyping of polymorphisms directly from genomic DNA via coupled amplification and sequencing (CAS)

Practical interpretation of CYP2D6 haplotypes: Comparison and integration of automated and expert calling

We describe a population genetic approach to compare samples interpreted with expert calling (EC) versus automated calling (AC) for CYP2D6 haplotyping. The analysis represents 4812 haplotype calls based on signal data generated by the Luminex xMap analyzers from 2406 patients referred to a high-complexity molecular diagnostics laboratory for CYP450 testing. DNA was extracted from buccal swabs. We compared the results of expert calls (EC) and automated calls (AC) with regard to haplotype number and frequency. The ratio of EC to AC was 1:3. Haplotype frequencies from EC and AC samples were convergent across haplotypes, and their distribution was not statistically different between the groups. Most duplications required EC, as only expansions with homozygous or hemizygous haplotypes could be automatedly called. High-complexity laboratories can offer equivalent interpretation to automated calling for non-expanded CYP2D6 loci, and superior interpretation for duplications. We have validated scientific expert calling specified by scoring rules as standard operating procedure integrated with an automated calling algorithm. The integration of EC with AC is a practical strategy for CYP2D6 clinical haplotyping.

Allele-specific long-range PCR/sequencing method for allelic assignment of multiple single nucleotide polymorphisms

We report an allele-specific sequencing method using allele-specific long-range polymerase chain reaction (PCR) to determine if multiple (specifically, more than three) single nucleotide polymorphisms (SNPs) are located on the same allele. We sequenced the glucocorticoid receptor (GR) gene as a model and detected four nucleotide changes, including two novel variations, in intron 4 and exons 6, 8, and 9 alpha in four of the investigated cell lines. The terminal SNPs (intron 4 and exon 9 alpha) were separated by 19 kb. Following SNP identification, the first round PCR allele-specific primers are designed at the both distal SNP sites (intron 4 and exon 9 alpha), placing the SNP positions at the primer 3'-end. Using these first round PCR products as template, the second round PCR was performed to separately amplify exons 6 and 8. These second round PCR products were subsequently sequenced. The sequencing results showed that the four SNPs were located on the same allele, i.e., forming a haplotype. This allele-specific long-range PCR/sequencing (ALP/S) method is rapid and applicable to the allelic assignment for more than three SNPs.

Molecular haplotyping of genomic DNA for multiple single-nucleotide polymorphisms located kilobases apart using long-range polymerase chain reaction and intramolecular ligation

Genetic polymorphisms are well-recognized causes of interindividual differences in disease risk and treatment response in humans. For genes containing multiple single-nucleotide polymorphisms (SNPs), haplotype structure is often the principal determinant of phenotypic consequences, and haplotype distribution represents the best approach for assessing patterns of linkage disequilibrium. To permit more widespread molecular determination of haplotypes, we developed a simple yet robust method to determine haplotype structure for multiple SNPs located up to 30 kb apart in genomic DNA using long-range polymerase chain reaction (LR-PCR) and intramolecular ligation. Complete concordance was shown between the new method and conventional approaches, such as family pedigree analysis or cloning and sequencing. The availability of a simple method to directly determine haplotype structure using genomic DNA, without family pedigree analysis, cloning or complex instrumentation, provides an important new tool for elucidating the genetic determinants of drug disposition and effects, disease risk, and molecular evolution.

Improvement of base-calling in multilane automated DNA sequencing by use of electrophoretic calibration standards, data linearization, and trace alignment

We present a new method for the linearization and alignment of data traces generated by multilane automated DNA sequencing instruments. Application of this method to data generated with the Visible Genetics Open Gene DNA sequencing system (using MicroCel 700 gel cassettes, with a 25 cm separation distance) allows read lengths of > 1,000 nucleotides to be routinely obtained with high confidence and > 97% accuracy. This represents an increase of 10-15% in average read length, relative to data from this system that have not been processed in the fashion described herein. Most importantly, the linearization and alignment method allows usable sequence to be obtained from a fraction of 10-15% of data sets which, because of original trace misalignment problems, would otherwise have to be discarded. Our method involves adding electrophoretic calibration standards to the DNA sequencing fragments. The calibration standards are labeled with a dye that differs spectrally from the dye attached to the sequencing fragments. The calibration standards are identical in all the lanes. Analysis of the mobilities of the calibration standards allows correction for both systematic and random variation of electrophoretic properties between gel lanes. We have successfully used this method with two-dye and three-dye DNA sequencing instruments.

A commented dictionary of techniques for genotyping

Several tools, differing in their technical and practical parameters, are available for the detection of point mutations as well as small deletions and insertions. In this article, a dictionary featuring over fifty methods for detection of mutation is presented. The distinguishing principle for each method is briefly explained. Sorting of and discussion on the methods give the reader a brief introduction to the field of genotyping.

Haplotypes and linkage disequilibrium at the phenylalanine hydroxylase locus, PAH, in a global representation of populations

Because defects in the phenylalanine hydroxylase gene (PAH) cause phenylketonuria (PKU), PAH was studied for normal polymorphisms and linkage disequilibrium soon after the gene was cloned. Studies in the 1980s concentrated on European populations in which PKU was common and showed that haplotype-frequency variation exists between some regions of the world. In European populations, linkage disequilibrium generally was found not to exist between RFLPs at opposite ends of the gene but was found to exist among the RFLPs clustered at each end. We have now undertaken the first global survey of normal variation and disequilibrium across the PAH gene. Four well-mapped single-nucleotide polymorphisms (SNPs) spanning approximately 75 kb, two near each end of the gene, were selected to allow linkage disequilibrium across most of the gene to be examined. These SNPs were studied as PCR-RFLP markers in samples of, on average, 50 individuals for each of 29 populations, including, for the first time, multiple populations from Africa and from the Americas. All four sites are polymorphic in all 29 populations. Although all but 5 of the 16 possible haplotypes reach frequencies >5% somewhere in the world, no haplotype was seen in all populations. Overall linkage disequilibrium is highly significant in all populations, but disequilibrium between the opposite ends is significant only in Native American populations and in one African population. This study demonstrates that the physical extent of linkage disequilibrium can differ substantially among populations from different regions of the world, because of both ancient genetic drift in the ancestor common to a large regional group of modern populations and recent genetic drift affecting individual populations.

High performance DNA sequencing, and the detection of mutations and polymorphisms, on the Clipper sequencer

The Visible Genetics Clipper sequencer is a new platform for automated DNA sequencing which employs disposable MicroCel cassettes and 50 microm thick polyacrylamide gels. Two DNA ladders can be analyzed simultaneously in each of 16 lanes on a gel, after labeling with far-red absorbing dyes such as Cy5 and Cy5.5. This allows a simultaneous bidirectional sequencing of four templates. We have evaluated the Clipper sequencer, by cycle-sequencing of an M13 single-stranded DNA standard, and by coupled amplification and sequencing (CLIP) of reverse-transcribed human immunodeficiency virus (HIV-1) RNA standards and clinical patient samples. (i) Limitations of instrument. We have examined basic instrument parameters such as detector stability, background, digital sampling rate, and gain. With proper usage, the optical and electronic subsystems of the Clipper sequencer do not limit the data collection or sequence-determination processes. (ii) Limitations of gel performance. We have also examined the physics of DNA band separation on 50 microm thick MicroCel gels. We routinely obtain well-resolved sequence which can be base-called with 98.5% accuracy to position approximately 450 on an 11 cm gel, and to position approximately 900 on a 25 cm gel. Resolution on 5 and 11 cm gels ultimately is limited by a sharp decrease in spacing between adjacent bands, in the biased reptation separation regime. Fick's (thermal) diffusion appears to be of minor importance on 6 cm or 11 cm gels, but becomes an additional resolution-limiting factor on 25 cm gels. (iii) Limitations of enzymology. Template quality, primer nesting, choice of DNA polymerase, and choice between dye primers and dye terminators are key determinants of the ability to detect mutations and polymorphisms on the Clipper sequencer, as on other DNA sequencers. When CLIP is used with dye-labeled primers and a DNA polymerase of the F667Y, delta(5'--> 3' exo) class, we can routinely detect single-nucleotide mutations and polymorphisms over the 0.35-0.65 heterozygosity range. We present an example of detecting therapeutically relevant mutations in a clinical HIV-1 RNA isolate.

Molecular haplotyping of genetic markers 10 kb apart by allele-specific long-range PCR

Haplotypes, combinations of polymorphic markers in a chromosome, are critical for genome diversity research. However, their utility in population samplings is compromised by uncertain linkage phase determinations from unrelated individuals. Molecular haplotyping accomplishes direct phase determination by generation of hemizygous templates from diploid genomic samples. We report molecular haplotyping by allele-specific long-range PCR of two markers 9.5 kb apart at the CD4 locus: a bi-allelic Alu deletion and a multi-allelic repeat. We verified CD4 molecular haplotypes by classical Mendelian analysis. Molecular haplotyping should prove useful in mapping disease genes and in establishing founder effects.

PCR assays of variable nucleotide sites for identification of conservation units

A number of authors have recently suggested that the best approach for identifying units of conservation is to follow a systematics model of character analysis (Amato, 1991; Cracraft, 1991; Vogler and DeSalle, 1994). This approach necessitates the use of an operational, typological, evolutionary species concept. The use of the phylogenetic species concept has the utility and philosophical logic appropriate for this task. Additionally, there is a large body of literature that uses this framework, along with a parsimony based character analysis to identify patterns of phylogeny (Cracraft, 1983; Nelson and Platnick, 1981; Nixon and Wheeler, 1990). While we advocate this approach, we recognize that one of its limiting factors is sample size. We propose that by selective direct sequencing plus rapid sampling of variable target characters by polymerase chain reaction (PCR) assays of specific sites, sufficiently large numbers of individuals can be accurately, inexpensively, and quickly surveyed for diagnostic characters. This procedure is demonstrated by a survey of variable nucleotide sites in the Caiman crocodilus complex.

Modeling of heteroduplex formation during PCR from mixtures of DNA templates

We have investigated the capability of PCR to amplify a specific locus from each template in a mixture of allelic DNAs. Modeling experiments employed a 300-bp HOX2B segment as target and utilized, as distinct template "alleles," genomic DNAs from 1 human and from 2 chimpanzees known to differ in sequence at the target. Two modes were used: (1) mixtures of PCR products that had been previously amplified individually from a single template and (2) PCR amplification en masse from composite human/chimpanzee genomic DNA templates. Products generated by either mode were separated by denaturing gradient gel electrophoresis (DGGE). Detection of a "trace" allele mixed with a "dominant" one was possible by simple ethidium bromide staining of the gel up to a sensitivity of 1 part in 20. A balanced mixture was represented by 5:5 and 4:3:3 mixtures of allelic PCR products or genomic templates; an uneven mixture of dominant and trace alleles, by 9:1 and 8:1:1 mixtures. For 5:5, two homoduplex bands and two heteroduplex bands of equal intensity were generated. For 9:1, the trace homoduplex disappears whereas the two heteroduplexes are easily visible. For 8:1:1, four heteroduplexes and one homoduplex were observed; homoduplexes and heteroduplexes formed from the trace alleles were not visible. These experiments demonstrate that PCR can amplify mixed allelic templates in direct proportion to the stoichiometric fraction of each template. Trace species are captured as heteroduplexes with the most abundant species and are clearly displaced on denaturing gradient gels from the dominant homoduplex species. Our analytical studies can be applied to analysis of sequence variants in DNA collected from cancerous or infected tissues.(ABSTRACT TRUNCATED AT 250 WORDS)