Long-read genome sequencing for the diagnosis of neurodevelopmental disorders

Sm, Hiatt; Lawlor, James M.J.; Lh, Handley; Rc, Ramaker; Bb, Rogers; Ec, Partridge; Lb, Boston; Williams, Melissa E.; Cb, Plott; Jenkins, Jerry; De, Gray; Jm, Holt; Km, Bowling; Em, Bebin; Grimwood, Jane; Schmutz, Jeremy; Gm, Cooper

doi:10.1101/2020.07.02.185447

Cited by 9 publications

(7 citation statements)

References 61 publications

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“…Here, we have analyzed, for the first time, two DM1 families carrying CTG repeats ranging from 170 to over 1000 CTG repeats using the Sequel II System. The Sequel II System generates longer reads, enabling higher CCS accuracy, and has higher throughputs than the Sequel and RSII Systems (data not shown and [ 18 , 42 , 43 ]). Here, the Sequel II System and bioinformatic tools give us the ability to simultaneously measure repeat numbers with high resolution, to resolve the complete sequence complex repeat expansions and to measure the degree of somatic mosaicism.…”

Section: Discussionmentioning

confidence: 99%

Robust Detection of Somatic Mosaicism and Repeat Interruptions by Long-Read Targeted Sequencing in Myotonic Dystrophy Type 1

Mangin

Pontual

Tsai

et al. 2021

IJMS

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Myotonic dystrophy type 1 (DM1) is the most complex and variable trinucleotide repeat disorder caused by an unstable CTG repeat expansion, reaching up to 4000 CTG in the most severe cases. The genetic and clinical variability of DM1 depend on the sex and age of the transmitting parent, but also on the CTG repeat number, presence of repeat interruptions and/or on the degree of somatic instability. Currently, it is difficult to simultaneously and accurately determine these contributing factors in DM1 patients due to the limitations of gold standard methods used in molecular diagnostics and research laboratories. Our study showed the efficiency of the latest PacBio long-read sequencing technology to sequence large CTG trinucleotides, detect multiple and single repeat interruptions and estimate the levels of somatic mosaicism in DM1 patients carrying complex CTG repeat expansions inaccessible to most methods. Using this innovative approach, we revealed the existence of de novo CCG interruptions associated with CTG stabilization/contraction across generations in a new DM1 family. We also demonstrated that our method is suitable to sequence the DM1 locus and measure somatic mosaicism in DM1 families carrying more than 1000 pure CTG repeats. Better characterization of expanded alleles in DM1 patients can significantly improve prognosis and genetic counseling, not only in DM1 but also for other tandem DNA repeat disorders.

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Section: Discussionmentioning

confidence: 99%

Robust Detection of Somatic Mosaicism and Repeat Interruptions by Long-Read Targeted Sequencing in Myotonic Dystrophy Type 1

Mangin

Pontual

Tsai

et al. 2021

IJMS

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“…In trio sequencing for rare disease, there is often greater importance in sequencing a child proband. To manage sequencing costs, studies often take the approach of sequencing the parents at a lower coverage than the child 36 . In order to evaluate performance in these scenarios, we performed downsampling of the parent samples while keeping the child coverage at 35x.…”

Section: Assessing the Effect Of Parental Depth On Variant Calling Accuracy In The Probandmentioning

confidence: 99%

DeepTrio: Variant Calling in Families Using Deep Learning

Kolesnikov

Goel

Nattestad

et al. 2021

Preprint

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Every human inherits one copy of the genome from their mother and another from their father. Parental inheritance helps us understand the transmission of traits and genetic diseases, which often involve de novo variants and rare recessive alleles. Here we present DeepTrio, which learns to analyze child-mother-father trios from the joint sequence information, without explicit encoding of inheritance priors. DeepTrio learns how to weigh sequencing error, mapping error, and de novo rates and genome context directly from the sequence data. DeepTrio has higher accuracy on both Illumina and PacBio HiFi data when compared to DeepVariant. Improvements are especially pronounced at lower coverages (with 20x DeepTrio roughly equivalent to 30x DeepVariant). As DeepTrio learns directly from data, we also demonstrate extensions to exome calling solely by changing the training data. DeepTrio includes pre-trained models for Illumina WGS, Illumina exome, and PacBio HiFi.

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“…We sequenced HG003, HG004, HG006, and HG007 with PacBio HiFi reads in order to contribute to Genome in a Bottle’s efforts to expand the confident regions. The high quality and mappability of PacBio HiFi data has recently proven instrumental in the first Telomere-to-Telomere human assembly[34] and undiagnosed rare disease[35]. Because we have sequence data for the same samples from PacBio HiFi and NovaSeq, we can quantify the differences in mappability and variant calling accuracy between the technologies.…”

Section: Resultsmentioning

confidence: 99%

An Extensive Sequence Dataset of Gold-Standard Samples for Benchmarking and Development

Baid

Nattestad

Kolesnikov

et al. 2020

Preprint

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Accurate standards and extensive development datasets are the foundation of technical progress. To facilitate benchmarking and development, we sequence 9 samples, covering the Genome in a Bottle truth sets on multiple instruments (NovaSeq, HiSeqX, HiSeq4000, PacBio Sequel II System) and sample preparations (PCR-Free, PCR-Positive) for both whole genome and multiple exome kits. We benchmark pipelines, quantifying strengths and limitations for sequencing and analysis methods. We identify variability within and between instruments, preparation methods, and analytical pipelines, across various sequencing depths. We discuss the relevance of this variability to downstream analyses, and strategies to reduce variability.

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Long-read genome sequencing for the diagnosis of neurodevelopmental disorders

Cited by 9 publications

References 61 publications

Robust Detection of Somatic Mosaicism and Repeat Interruptions by Long-Read Targeted Sequencing in Myotonic Dystrophy Type 1

Robust Detection of Somatic Mosaicism and Repeat Interruptions by Long-Read Targeted Sequencing in Myotonic Dystrophy Type 1

DeepTrio: Variant Calling in Families Using Deep Learning

An Extensive Sequence Dataset of Gold-Standard Samples for Benchmarking and Development

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