Xiangfeng Cui scite author profile

We have developed an in vitro method for amplifying a large fraction of the DNA sequences present in a single haploid cell by repeated primer extensions using a mixture of 15-base random oligonucleotides. We studied 12 genetic loci and estimate that the probability of amplifying any sequence in the genome to a minimum of 30 copies is not less than 0.78 (95% confidence). Whole genome amplification beginning with a single cell, or other samples with very small amounts of DNA, has significant implications for multipoint mapping by sperm or oocyte typing and possibly for genetic disease diagnosis, forensics, and the analysis of ancient DNA samples.

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Amplification and analysis of DNA sequences in single human sperm and diploid cells

Gyllensten²,

Cui

et al. 1988

Nature

622

223

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Single-sperm typing: determination of genetic distance between the G gamma-globin and parathyroid hormone loci by using the polymerase chain reaction and allele-specific oligomers.

Cui

Goradia

et al. 1989

Proc. Natl. Acad. Sci. U.S.A.

178

121

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The frequency of recombination between the Gy-globin (HBG2) and parathyroid hormone (PTH) loci on the short arm of human chromosome 11 was estimated by typing >700 single-sperm samples from two males. The sperm-typing technique employed involves the polymerase chain reaction and allele-specific oligonucleotide hybridization. Our maximum likelihood recombination fraction estimate of 0.16 (95% confidence interval, 0.13-0.19) falls well within previous estimates based on family studies. With current technology and a sample size of 1000 sperm, recombination fractions down to =0.009 can be estimated with statistical reliability; with a sample size of 5000 sperm, this value drops to about 0.004. Reasonable technological improvements could result in the detection of recombination frequencies <0.001.The determination of genetic linkage between polymorphic markers in humans has traditionally depended upon pedigree analysis. Such studies have a number of inherent difficulties when compared to linkage analysis in experimental organisms. Humans of the appropriate genotypes cannot be crossed at will. In those crosses that are available, linkage phase is often unknown; this uncertainty blurs the distinction between recombinants and nonrecombinants. Finally, the difficulty in obtaining large numbers of offspring from families informative for a particular set of genetic markers effectively limits statistically reliable recombination frequency estimates to 0.01 or 0.02 (i.e., 1 or 2 centimorgans). A radically different approach to measuring recombination frequency has been suggested (1) that has a number of advantages when compared to traditional family studies. This approach has, as its basis, the direct molecular analysis of DNA sequences in single meiotic products. The method uses the polymerase chain reaction (PCR) (2-4) to amplify polymorphic DNA sequences at two or more genetic loci in a single sperm. Analysis of single human sperm by this typing procedure has already demonstrated Mendelian segregation of alleles at each of two loci and independent assortment of genes on nonhomologous chromosomes (1). With sperm typing a direct count of recombinant and nonrecombinant meiotic products can be made and used to estimate recombination frequency. Since a single human semen sample contains >300 million sperm, this approach is not limited by sample-size considerations and is capable of high-resolution genetic mapping.Before embarking on studies to measure very small recombination fractions using the sperm-typing approach, we thought it prudent to estimate the frequency of recombination between two loci whose genetic distance from one another had already been determined by pedigree analysis. We have, therefore, estimated by sperm typing the recombination fraction between the parathyroid hormone gene locus (PTH) and the Gy-globin gene locus (HBG2) on the short arm of human chromosome 11. In these experiments, we examined 708 sperm samples from two males. We have also developed a mathematical approach for analyzing sperm-typi...

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A genotyping system capable of simultaneously analyzing >1000 single nucleotide polymorphisms in a haploid genome

et al. 2005

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A high-throughput genotyping system for scoring single nucleotide polymorphisms (SNPs) has been developed. With this system, >1000 SNPs can be analyzed in a single assay, with a sensitivity that allows the use of single haploid cells as starting material. In the multiplex polymorphic sequence amplification step, instead of attaching universal sequences to the amplicons, primers that are unlikely to have nonspecific and productive interactions are used. Genotypes of SNPs are then determined by using the widely accessible microarray technology and the simple single-base extension assay. Three SNP panels, each consisting of >1000 SNPs, were incorporated into this system.The system was used to analyze 24 human genomic DNA samples. With 5 ng of human genomic DNA, the average detection rate was 98.22% when single probes were used, and 96.71% could be detected by dual probes in different directions. When single sperm cells were used, 91.88% of the SNPs were detectable, which is comparable to the level that was reached when very few genetic markers were used. By using a dual-probe assay, the average genotyping accuracy was 99.96% for 5 ng of human genomic DNA and 99.95% for single sperm. This system may be used to significantly facilitate large-scale genetic analysis even if the amount of DNA template is very limited or even highly degraded as that obtained from paraffin-embedded cancer specimens, and to make many unpractical research projects highly realistic and affordable.

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Direct electrophoretic detection of the allelic state of single DNA molecules in human sperm by using the polymerase chain reaction.

Cui

Arnheim

1990

Proc. Natl. Acad. Sci. U.S.A.

117

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We have developed a procedure that allows the detection of polymerase chain reaction (PCR) products derived from a single target DNA molecule in a human sperm without using radioactive probes. With this method, three genetic loci present in a single sperm can be amplified simultaneously. The amplification procedure is specific as well as efficient and permits detection of the PCR product by ethidium bromide staining after polyacrylamide gel electrophoresis. When allele-specific PCR primers that differ in length are used, the size of the PCR products of different alleles also vary in length, allowing the allelic state at each locus to be determined electrophoretically. Studies on individual sperm by using this procedure should facilitate the measurement of genetic recombination in humans over small physical distances. The ability to directly analyze the allelic state of PCR products from one cell rapidly and simply will also be useful for the prenatal diagnosis of genetic disease, especially in the analysis of single blastomeres taken from in vitro fertilized eggs prior to implantation.

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Xiangfeng Cui

Whole genome amplification from a single cell: implications for genetic analysis.

Amplification and analysis of DNA sequences in single human sperm and diploid cells

Single-sperm typing: determination of genetic distance between the G gamma-globin and parathyroid hormone loci by using the polymerase chain reaction and allele-specific oligomers.

A genotyping system capable of simultaneously analyzing >1000 single nucleotide polymorphisms in a haploid genome

Direct electrophoretic detection of the allelic state of single DNA molecules in human sperm by using the polymerase chain reaction.

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