Recent advances in the detection of repeat expansions with short-read next-generation sequencing

Bahlo, Melanie; Bennett, Mark F; Degorski, Peter; Tankard, Rick M.; Delatycki, Martin B.; Lockhart, Paul J.

doi:10.12688/f1000research.13980.1

Cited by 103 publications

(96 citation statements)

References 30 publications

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“…Existing methods for repeat expansion detection rely upon predefined repeat catalogs [22][23][24][25][26]38 . Although these methods can analyze user-defined catalogs, defining the genomic locations of repeats is a complex task and there is a risk of missing many potentially-pathogenic loci.…”

Section: Genome Wide Catalogs Are Limitingmentioning

confidence: 99%

ExpansionHunter Denovo: A computational method for locating known and novel repeat expansions in short-read sequencing data

Dolzhenko

Bennett

Richmond

et al. 2019

Preprint

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AbstractExpansions of short tandem repeats are responsible for over 40 monogenic disorders, and undoubtedly many more pathogenic repeat expansions (REs) remain to be discovered. Existing methods for detecting REs in short-read sequencing data require predefined repeat catalogs. However recent discoveries have emphasized the need for detection methods that do not require candidate repeats to be specified in advance. To address this need, we introduce ExpansionHunter Denovo, an efficient catalog-free method for genome-wide detection of REs. Analysis of real and simulated data shows that our method can identify large expansions of 41 out of 44 pathogenic repeats, including nine recently reported non-reference REs not discoverable via existing methods.ExpansionHunter Denovo is freely available at https://github.com/Illumina/ExpansionHunterDenovo

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Section: Genome Wide Catalogs Are Limitingmentioning

confidence: 99%

ExpansionHunter Denovo: A computational method for locating known and novel repeat expansions in short-read sequencing data

Dolzhenko

Bennett

Richmond

et al. 2019

Preprint

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“…These techniques are only applicable to a specific target region and not scalable to high-throughput analysis, which limits the possibility of genome-wide TR analysis. In the recent decade, significant progress has been made in utilising high throughput short-read sequencing data for genotyping STRs [10]. Our group and others have also demonstrated targeted sequencing approaches using short-read sequencing for TR analysis [11, 12].…”

Section: Introductionmentioning

confidence: 99%

High-throughput multiplexed tandem repeat genotyping using targeted long-read sequencing

Ganesamoorthy

Yan

Murigneux

et al. 2019

Preprint

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3Tandem repeats (TRs) are highly prone to variation in copy numbers due to their repetitive and 2 4 unstable nature, which makes them a major source of genomic variation between individuals. 5However, population variation of TRs have not been widely explored due to the limitations of 2 6 existing tools, which are either low-throughput or restricted to a small subset of TRs. Here, we 2 7used SureSelect targeted sequencing approach combined with Nanopore sequencing to 2 8 overcome these limitations. We achieved an average of 3062-fold target enrichment on a panel 2 9 of 142 TR loci, generating an average of 97X sequence coverage on 7 samples utilizing 2 3 0 MinION flow-cells with 200ng of input DNA per sample. We identified a subset of 110 TR loci 3 1with length less than 2kb, and GC content greater than 25% for which we achieved an average 3 2 genotyping rate of 75% and increasing to 91% for the highest-coverage sample. Alleles 3 3 estimated from targeted long-read sequencing were concordant with gold standard PCR sizing 3 4 analysis and moreover highly correlated with alleles estimated from whole genome long-read 3 5sequencing. We demonstrate a targeted long-read sequencing approach that enables 3 6

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“…Methodological advances in bioinformatics in the last two years have made the simultaneous testing for all known REs through whole genome sequencing (WGS) feasible [2] . Additionally, multiple novel REs have been discovered in neurological disorders using WGS in the last two years alone, including in epilepsy [3] and ataxia [4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Rapid diagnosis of SCA36 in a three-generation family using short-read whole genome sequencing data

Rafehi

Szmulewicz

Pope

et al. 2019

Preprint

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Background: Spinocerebellar ataxias (SCA) are often caused by expansions of short tandem repeats (STRs). Recent methodological advances have made repeat expansion (RE) detection with whole genome sequencing (WGS) feasible. Objectives: To determine the genetic basis of ataxia in a large, multigenerational Australian pedigree, with autosomal dominant inheritance and possible anticipation. Methods and Results: WGS was performed on three affected relatives. The sequence data was screened for known pathogenic REs using three repeat expansion detection tools: exSTRa, ExpansionHunter and GangSTR. This screen provided a clear and rapid diagnosis (<5 days from receiving the sequencing data) of SCA36, a very rare form of ataxia which is caused by an intronic hexanucleotide GGCCTG RE in NOP56. Conclusions:We have demonstrated that diagnosis of rare ataxias caused by REs is highly feasible and cost effective with WGS. We propose a change in current clinical practice, such that WGS be implemented as the frontline, cost effective methodology for molecular testing of individuals with a clinical diagnosis of ataxia.

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Recent advances in the detection of repeat expansions with short-read next-generation sequencing

Cited by 103 publications

References 30 publications

ExpansionHunter Denovo: A computational method for locating known and novel repeat expansions in short-read sequencing data

ExpansionHunter Denovo: A computational method for locating known and novel repeat expansions in short-read sequencing data

High-throughput multiplexed tandem repeat genotyping using targeted long-read sequencing

Rapid diagnosis of SCA36 in a three-generation family using short-read whole genome sequencing data

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