Next Generation Diagnostics in Inherited Arrhythmia Syndromes

Genetic subtypes of inherited cardiac conditions (ICCs), such as long QT (LQT) syndrome, are associated with distinct patterns of risk and a molecular diagnosis can be used to direct clinical management [1‐5] and permit cascade screening in families, which is more effective than clinical screening alone [6]. However, ICCs are genetically heterogeneous [7] and conventional sequencing of ICC genes is expensive, time-consuming and rarely and inequitably applied in clinical practise, notwithstanding published guidelines [6].

The maturation of recently developed next generation sequencing (NGS) technologies provides unprecedented sequencing capacity at dramatically lower cost, and NGS has been implemented by some healthcare providers in the US and Europe for clinical diagnostics of ICCs (e.g., GeneDx, USA; Sistemas Genómicos, Spain; Oxford Molecular Genetics, UK). To date there have been no published studies that address the specific challenges of applying NGS technologies to inherited arrhythmia syndromes that include LQT syndrome, Brugada syndrome (BrS) and catecholaminergic polymorphic VT (CPVT).

A major challenge associated with targeted NGS is efficient and specific enrichment of disease genes prior to sequencing as, unlike Sanger sequencing [8], NGS approaches have no intrinsic target specificity [9]. To achieve target enrichment prior to NGS, DNA libraries are most commonly enriched for sequences of interest by PCR- or hybridization-based methods. PCR-based methods are typically multiplexed or parallelised in order to produce amplicons on a scale appropriate for NGS. Mature parallel approaches may separate PCR reactions in microdroplets (e.g., RDT 1000, RainDance Technologies) or microfluidic chips (e.g., Access Array, Fluidigm) before pooling amplicons. More recently, kits for pooled ultrahigh-multiplex PCR have been released (e.g., Ion Ampliseq, Life Technologies). The first generation Access Array is appropriate for targeted resequencing of small (<25,000 bp) regions: a library of 48 amplicons can be prepared from each of 48 samples in parallel (2,304 independent PCR reactions) in less than a day, and with little hands-on time [10]. Hybridisation approaches use specific labelled oligonucleotide baits to separate DNA containing sequences of interest from background, either in solution or bound to a microarray chip. Examples include SeqCap EZ Library (in-solution) and Sequence Capture Arrays (both Roche NimbleGen), TruSeq in-solution (Illumina) and the SureSelect in-solution system (Agilent Technologies). These provide off-the-shelf solutions to capture the whole exome, and customized versions for user-defined targets, the SureSelect custom system having a capacity of up to 6 Mb [11, 12].

NGS platforms are often divided into two categories on the basis of the length of sequence reads that they produce. Perhaps the most established long-read platform is the 454 GS FLX (454 Life Sciences, Roche) that produces reads of up to 1,000 bp. The smaller, table-top GS junior platform (also Roche) produces 400-bp reads and a total sequencing output of ~40 Mbp (10-h run). Short-read platforms, such as the Illumina Genome Analyzer II, Illumina HiSeq 2000 (Illumina), Applied Biosystems SOLiD v4 and SOLiD 5500 series (Life Technologies), typically have a significantly higher throughput than the long-read platforms, making them more suitable for sequencing a larger number of genes.

Here we present a comparison of two distinct approaches for NGS high-throughput diagnostics of genes causing inherited arrhythmia syndromes: PCR-based target enrichment using the Access Array followed by long-read sequencing on the GS junior (PCR-LR) and enrichment by SureSelect in-solution hybridization with short-read SOLiD v4 sequencing (Hyb-SR).