DNA Sudoku—harnessing high-throughput sequencing for multiplexed specimen analysis

Erlich, Yaniv; Chang, Kenneth; Gordon, Assaf; Ronen, Roy; Navon, Oron; Rooks, Michelle; Hannon, Gregory J.

doi:10.1101/gr.092957.109

Cited by 147 publications

(189 citation statements)

References 26 publications

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“…The extraction of as much statistical information as possible at cost as low as possible has therefore already attracted considerable interest. See, for instance, Jiang et al (2009) for the modeling of sequencing errors and Erlich et al (2009) for the efficient tagging of sequences.…”

Section: N Ext Generation Sequencing (Ngs) Is About Tomentioning

confidence: 99%

The Next Generation of Molecular Markers From Massively Parallel Sequencing of Pooled DNA Samples

2010

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Next generation sequencing (NGS) is about to revolutionize genetic analysis. Currently NGS techniques are mainly used to sequence individual genomes. Due to the high sequence coverage required, the costs for population-scale analyses are still too high to allow an extension to nonmodel organisms. Here, we show that NGS of pools of individuals is often more effective in SNP discovery and provides more accurate allele frequency estimates, even when taking sequencing errors into account. We modify the population genetic estimators Tajima's p and Watterson's u to obtain unbiased estimates from NGS pooling data. Given the same sequencing effort, the resulting estimators often show a better performance than those obtained from individual sequencing. Although our analysis also shows that NGS of pools of individuals will not be preferable under all circumstances, it provides a cost-effective approach to estimate allele frequencies on a genome-wide scale. N EXT generation sequencing (NGS) is about to revolutionize biology. Through a massive parallelization, NGS provides an enormous number of reads, which permits sequencing of entire genomes at a fraction of the costs for Sanger sequencing. Hence, for the first time it has become feasible to obtain the complete genomic sequence for a large number of individuals. For several organisms, including humans, Drosophila melanogaster, and Arabidopsis thaliana, large resequencing projects are well on their way. Nevertheless, despite the enormous cost reduction, genome sequencing on a population scale is still out of reach for the budget of most laboratories. The extraction of as much statistical information as possible at cost as low as possible has therefore already attracted considerable interest. See, for instance, Jiang et al. Current genome-wide resequencing projects collect the sequences individual by individual. To obtain full coverage of the entire genome and to have high confidence that all heterozygous sites were discovered, it is required that genomes are sequenced at a sufficiently high coverage. As many of the reads provide only redundant information, cost could be reduced by a more effective sampling strategy.In this report, we explore the potential of DNA pooling to provide a more cost-effective approach for SNP discovery and genome-wide population genetics. Sequencing a large pool of individuals simultaneously keeps the number of redundant DNA reads low and provides thus an economic alternative to the sequencing of individual genomes. On the other hand, more care has to be taken to establish an appropriate control of sequencing errors. Obviously haplotype information is not available from pooling experiments, but this will often be outweighed by the increased accuracy in population genetic inference.Focusing on biallelic loci, our analysis shows that with sufficiently large pool sizes, pooling usually outperforms the separate sequencing of individuals, both for estimating allele frequencies and for inference of population genetic parameters. When sequencing...

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Section: N Ext Generation Sequencing (Ngs) Is About Tomentioning

confidence: 99%

The Next Generation of Molecular Markers From Massively Parallel Sequencing of Pooled DNA Samples

2010

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“…Multiplexed scheme (Erlich et al, 2009) In this scheme, several pooling groups are created and the individuals are assigned to pools in each group by taking use of the Chinese remainder, one of the most ancient and fundamental in number theory (Andrews 1994;Ding et al 1996;Cormen et al 2001). To create a pooling groups design, the rule of pooling for group is = , which brings the , + , + , individuals to the th pools of group , where < and = , , .…”

Section: Shifted-transversal Designmentioning

confidence: 99%

The Application of Pooled DNA Sequencing in Disease Association Study

Lin¹,

Wang²

2012

DNA Sequencing - Methods and Applications

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“…In a previous work, by Prabhu and Pe'er [2] , overlapping pools were used, elegantly designed based on Error-Correcting-Codes, enabling the detection of only a single carrier. In another work by Erlich et al [3], a pooling strategy based on the Chinese-Reminder Theorem was employed to solve a slightly different problem. These designs offer a significant saving in resources, as they enable genotype reconstruction for N individuals, by using only O(log N ) or O( √ N ) pools, respectively.…”

Section: Introductionmentioning

confidence: 99%

Compressed sensing-based pooling experiments using next generation sequencing

Shental

Almasi‐Hashiani

Zuk

2010

2010 Information Theory and Applications Workshop (ITA)

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Abstract-Screening for carriers of rare variants by resequencing is important for the identification of individuals carrying disease alleles. Rapid sequencing by new technologies enables lowcost resequencing of target regions, although it is still prohibitive to test more than a few individuals. Pooling designs can enable detection of carriers of rare alleles in groups of individuals in a more economical manner. Previous pooling strategies were shown only for a relatively low number of individuals in a pool, and required the design of pooling schemes for particular cases. We propose a novel pooling design, based on a compressed sensing approach, which is general, simple and efficient. We model the experimental procedure and show via computer simulations our ability to recover rare allele carriers in larger groups than were possible before, especially when high coverage is obtained for each individual.

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DNA Sudoku—harnessing high-throughput sequencing for multiplexed specimen analysis

Cited by 147 publications

References 26 publications

The Next Generation of Molecular Markers From Massively Parallel Sequencing of Pooled DNA Samples

The Next Generation of Molecular Markers From Massively Parallel Sequencing of Pooled DNA Samples

The Application of Pooled DNA Sequencing in Disease Association Study

Compressed sensing-based pooling experiments using next generation sequencing

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