Whole-genome haplotyping using long reads and statistical methods

Kuleshov, Volodymyr; Xie, Dan; Chen, Rui; Pushkarev, Dmitry; Ma, Zhihai; Blauwkamp, Tim; Kertesz, Michael A.; Snyder, M

doi:10.1038/nbt.2833

Cited by 176 publications

(178 citation statements)

References 32 publications

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“…In contrast to dilution-based synthetic read approaches [17][18][19], the intramolecular circularization step in our protocol makes it possible to prepare a library in a single tube. We further exploited this property to allow multiple samples to be combined and prepared in the same mixture, yielding considerable savings in cost and time.…”

Section: Resultsmentioning

confidence: 99%

“…"True" long read technologies such as Pacific Biosciences SMRT sequencing and nanopore technologies [10,11] have proven invaluable in select applications, but require extensive computational error correction [12,13]. As an alternative, sample preparation protocols have emerged that enable long "synthetic" reads to be constructed from conventional short reads [14][15][16][17][18][19][20][21]. However, these approaches have been limited by generalizability, cost, throughput, or synthetic read length.…”

Section: Introductionmentioning

confidence: 99%

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Haplotype-phased synthetic long reads from short-read sequencing

Stapleton

Kim

Hamilton

et al. 2015

Preprint

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Next-generation DNA sequencing has revolutionized the study of biology. However, the short read lengths of the dominant instruments complicate assembly of complex genomes and haplotype phasing of mixtures of similar sequences. Here we demonstrate a method to reconstruct the sequences of individual nucleic acid molecules up to 11.6 kilobases in length from short (150-bp) reads. We show that our method can construct 99.97%-accurate synthetic reads from bacterial, plant, and animal genomic samples, full-length mRNA sequences from human cancer cell lines, and individual HIV env gene variants from a mixture. The preparation of multiple samples can be multiplexed into a single tube, further reducing effort and cost relative to competing approaches. Our approach generates sequencing libraries in three days from less than one microgram of DNA in a single-tube format without custom equipment or specialized expertise.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Haplotype-phased synthetic long reads from short-read sequencing

Stapleton

Kim

Hamilton

et al. 2015

Preprint

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“…An alternative approach used in LFR (Peters et al 2012), CPTseq (Amini et al 2014), and Illumina TruSeq Synthetic Long-Reads (previously known as Moleculo) (Kuleshov et al 2014) utilizes accurate short-read sequencing of long DNA fragments in order to obtain long-range information at high nucleotide accuracy. The Illumina TruSeq protocol is able to produce 10-kbp long reads, retaining the benefits of the highly accurate and cost-effective Illumina technology (Kuleshov et al 2014) and enabling human genome phasing (Kuleshov et al 2014) and de novo assembly of complex genomes (Voskoboynik et al 2013;McCoy et al 2014).…”

mentioning

confidence: 99%

“…The Illumina TruSeq protocol is able to produce 10-kbp long reads, retaining the benefits of the highly accurate and cost-effective Illumina technology (Kuleshov et al 2014) and enabling human genome phasing (Kuleshov et al 2014) and de novo assembly of complex genomes (Voskoboynik et al 2013;McCoy et al 2014).…”

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confidence: 99%

“…Under Illumina's synthetic long-read protocol, DNA sequencing libraries are prepared as follows: First, the genomic DNA is sheared into long (≥10 kbp) fragments and ligated with amplification adapters at both ends; second, these molecules are diluted into wells so that each well receives only a small fraction (1%-2%) of the genome; third, molecules are amplified, sheared into short fragments, and uniquely barcoded within each well (Kuleshov et al 2014). The individual wells are then pooled and sequenced together.…”

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confidence: 99%

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Read Clouds Uncover Variation in Complex Regions of the Human Genome

Bishara

Liu

Kashef-Haghighi

et al. 2015

Lecture Notes in Computer Science

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Although an increasing amount of human genetic variation is being identified and recorded, determining variants within repeated sequences of the human genome remains a challenge. Most population and genome-wide association studies have therefore been unable to consider variation in these regions. Core to the problem is the lack of a sequencing technology that produces reads with sufficient length and accuracy to enable unique mapping. Here, we present a novel methodology of using read clouds, obtained by accurate short-read sequencing of DNA derived from long fragment libraries, to confidently align short reads within repeat regions and enable accurate variant discovery. Our novel algorithm, Random Field Aligner (RFA), captures the relationships among the short reads governed by the long read process via a Markov Random Field. We utilized a modified version of the Illumina TruSeq synthetic long-read protocol, which yielded shallow-sequenced read clouds. We test RFA through extensive simulations and apply it to discover variants on the NA12878 human sample, for which shallow TruSeq read cloud sequencing data are available, and on an invasive breast carcinoma genome that we sequenced using the same method. We demonstrate that RFA facilitates accurate recovery of variation in 155 Mb of the human genome, including 94% of 67 Mb of segmental duplication sequence and 96% of 11 Mb of transcribed sequence, that are currently hidden from short-read technologies.

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Overview of ApproachesFrom Whole‐Community Shotgun Sequencing to Single‐Cell Genomics

2018

Genomic Approaches in Earth and Environmental Sciences

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Whole-genome haplotyping using long reads and statistical methods

Cited by 176 publications

References 32 publications

Haplotype-phased synthetic long reads from short-read sequencing

Haplotype-phased synthetic long reads from short-read sequencing

Read Clouds Uncover Variation in Complex Regions of the Human Genome

Overview of ApproachesFrom Whole‐Community Shotgun Sequencing to Single‐Cell Genomics

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