Unravelling undiagnosed rare disease cases by HiFi long-read genome sequencing

Steyaert, Wouter; Sagath, Lydia; Demidov, German; Yépez, Vicente A.; Esteve-Codina, Anna; Gagneur, Julien; Ellwanger, Kornelia; Derks, Ronny; Weiss, Marjan; den Ouden, Amber; van den Heuvel, Simone; Swinkels, Hilde; Zomer, Nick; Steehouwer, Marloes; O’Gorman, Luke; Astuti, Galuh; Neveling, Kornelia; Schüle, Rebecca; Xu, Jishu; Synofzik, Matthis; Beijer, Danique; Hengel, Holger; Schöls, Ludger; Claeys, Kristl G; Baets, Jonathan; Van de Vondel, Liedewei; Ferlini, Alessandra; Selvatici, Rita; Morsy, Heba; Saeed Abd Elmaksoud, Marwa; Straub, Volker; Müller, Juliane; Pini, Veronica; Perry, Luke; Sarkozy, Anna; Zaharieva, Irina; Muntoni, Francesco; Bugiardini, Enrico; Polavarapu, Kiran; Horvath, Rita; Reid, Evan; Lochmüller, Hanns; Spinazzi, Marco; Savarese, Marco; ,; ,; ,; ,; Matalonga, Leslie; Laurie, Steven; Brunner, Han G.; Graessner, Holm; Beltran, Sergi; Ossowski, Stephan; Vissers, Lisenka E.L.M.; Gilissen, Christian; Hoischen, Alexander

doi:10.1101/2024.05.03.24305331

Cited by 6 publications

References 52 publications

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Advancing long-read nanopore genome assembly and accurate variant calling for rare disease detection

Negi,

Stenton,

Berger

et al. 2024

Preprint

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More than 50% of families with suspected rare monogenic diseases remain unsolved after whole genome analysis by short read sequencing (SRS). Long-read sequencing (LRS) could help bridge this diagnostic gap by capturing variants inaccessible to SRS, facilitating long-range mapping and phasing, and providing haplotype-resolved methylation profiling. To evaluate LRS's additional diagnostic yield, we sequenced a rare disease cohort of 98 samples, including 41 probands and some family members, using nanopore sequencing, achieving per sample ~36x average coverage and 32 kilobase (kb) read N50 from a single flow cell. Our Napu pipeline generated assemblies, phased variants, and methylation calls. LRS covered, on average, coding exons in ~280 genes and ~5 known Mendelian disease genes that were not covered by SRS. In comparison to SRS, LRS detected additional rare, functionally annotated variants, including SVs and tandem repeats, and completely phased 87% of protein-coding genes. LRS detected additional de novo variants, and could be used to distinguish postzygotic mosaic variants from prezygotic de novos. Eleven probands were solved, with diverse underlying genetic causes including de novo and compound heterozygous variants, large-scale SVs, and epigenetic modifications. Our study demonstrates LRS's potential to enhance diagnostic yield for rare monogenic diseases, implying utility in future clinical genomics workflows.

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Advancing long-read nanopore genome assembly and accurate variant calling for rare disease detection

Negi,

Stenton,

Berger

et al. 2024

Preprint

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HiFi long-read genomes for difficult-to-detect clinically relevant variants

Höps,

Weiss,

Derks

et al. 2024

Preprint

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Clinical short-read exome and genome sequencing approaches have positively impacted diagnostic testing for rare diseases. Yet, technical limitations associated with short reads challenge their use for detection of disease-associated variation in complex regions of the genome. Long-read sequencing (LRS) technologies may overcome these challenges, potentially qualifying as a first-tier test for all rare diseases. To test this hypothesis, we performed LRS (30x HiFi genomes) for 100 samples with 145 known clinically relevant germline variants that are challenging to detect using short-read sequencing and necessitate a broad range of complementary test modalities in diagnostic laboratories. We show that relevant variant callers readily re-identify the majority of variants (120/145, 83%), including ~90% of structural variants, SNVs/InDels in homologous sequences and expansions of short tandem repeats. Another 10% (n=14) was visually apparent in the data but not automatically detected. Our analyses also identified systematic challenges for the remaining 7% (n=11) of variants such as the detection of AG-rich repeat expansions. Titration analysis showed that 89% of all automatically called variants could also be identified using 15-fold coverage. Thus, long-read genomes identified 93% of pathogenic variants that are most challenging to detect using short-read technologies. Even with reduced coverage, the vast majority of variants remained detectable, possibly enhancing cost-effective diagnostic implementation. Most importantly, we show the potential to use a single technology to accurately identify all types of clinically relevant variants.

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Structural variation in nebulin and its implications on phenotype and inheritance: establishing a dominant distal phenotype caused by large deletions

Sagath,

Kiiski,

Naidu

et al. 2024

Preprint

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Introduction: Structural variants (SVs) of the nebulin gene (NEB), including intragenic duplications, deletions, and copy number variation of the triplicate region, are an established cause of recessively inherited nemaline myopathies and related neuromuscular disorders. Large deletions have been shown to cause dominantly inherited distal myopathies. Here we provide an overview of 35 families with muscle disorders caused by such SVs inNEB. Methods: Using custom Comparative Genomic Hybridization arrays, exome sequencing, short-read genome sequencing, custom Droplet Digital PCR, or Sanger sequencing, we identified pathogenic SVs in 35 families withNEB-related myopathies. Results: In 23 families, recessive intragenic deletions and duplications or pathogenic gains of the triplicate region segregating with the disease in compound heterozygous form, together with a small variant in trans, were identified. In two families the SV was, however, homozygous. Eight families have not been described previously. In 12 families with a distal myopathy phenotype, eight unique, large deletions encompassing 52 to 97 exons in either heterozygous (n = 10) or mosaic (n = 2) state were identified. In the families where inheritance was recessive, no correlation could be made between the types of variants and the severity of the disease. In contrast, all patients with large dominant deletions inNEBhad milder, predominantly distal muscle weakness. Discussion: For the first time, we establish a clear and statistically significant association between largeNEBdeletions and a form of distal myopathy. In addition, we provide the hitherto largest overview of the spectrum of SVs inNEB.

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Unravelling undiagnosed rare disease cases by HiFi long-read genome sequencing

Cited by 6 publications

References 52 publications

Advancing long-read nanopore genome assembly and accurate variant calling for rare disease detection

Advancing long-read nanopore genome assembly and accurate variant calling for rare disease detection

HiFi long-read genomes for difficult-to-detect clinically relevant variants

Structural variation in nebulin and its implications on phenotype and inheritance: establishing a dominant distal phenotype caused by large deletions

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