Targeted re-sequencing of F8, F9 and VWF: Characterization of Ion Torrent data and clinical implications for mutation screening.

Eric Manderstedt,Rosanna Nilsson,Jan Astermark,Christer Halldén,Rolf Ljung,Christina Lind-Halldén,Pablo Garcia De Frutos

doi:10.1371/journal.pone.0216179

Eric Manderstedt, Rosanna Nilsson + Show 5 more

Open Access

https://doi.org/10.1371/journal.pone.0216179

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Journal: PloS one	Publication Date: Apr 26, 2019
Citations: 5	License type: CC BY 4.0

Affiliation: Kristianstad University, Skåne University Hospital

Abstract

Mutations are not identified in ~5% of hemophilia A and 10–35% of type 1 VWD patients. The bleeding tendency also varies among patients carrying the same causative mutation, potentially indicating variants in additional genes modifying the phenotype that cannot be identified by routine single-gene analysis. The F8, F9 and VWF genes were analyzed in parallel using an AmpliSeq strategy and Ion Torrent sequencing. Targeting all exonic positions showed an average read depth of >2000X and coverage close to 100% in 24 male patients with known disease-causing mutations. Discrimination between reference alleles and alternative/indel alleles was adequate at a 25% frequency threshold. In F8, F9 and VWF there was an absolute majority of all reference alleles at allele frequencies >95% and the average alternative allele and indel frequencies never reached above 10% and 15%, respectively. In VWF, 4–5 regions showed lower reference allele frequencies; in two regions covered by the pseudogene close to the 25% cut-off for reference alleles. All known mutations, including indels, gross deletions and substitutions, were identified. Additional VWF variants were identified in three hemophilia patients. The presence of additional mutations in 2 out of 16 (12%) randomly selected hemophilia patients indicates a potential mutational contribution that may affect the disease phenotype and counseling in these patients. Parallel identification of disease-causing mutations in all three genes not only confirms the deficiency, but differentiates phenotypic overlaps and allows for correct genetic counseling.

Highlights

The multiplex primer pools were optimized such that the primers systems with the lowest read depths in a specific pool were added to the other pool, excluding overlapping systems
Targeted re-sequencing of F8, F9 and von Willebrand factor (VWF) was optimized and validated in the present study using an AmpliSeq-based Ion Torrent sequencing strategy
The multiplex primer pools were optimized so that the primers systems with the lowest read depths in a specific pool were added to the other pool, excluding overlapping systems

Summary

Introduction

The common inherited bleeding disorders, von Willebrand disease (VWD), hemophilia A (HA) and hemophilia B (HB), account for 95–97% of such patients [2]. The bleeding tendency varies among patients carrying the same causative mutation, potentially indicating additional genes modifying the phenotype which cannot be identified by routine single-gene analysis [6]. A number of generation sequencing (NGS)-based studies have been used to re-sequence panels of genes associated with inherited bleeding disorders in a single workflow. To enable simultaneous mutation detection in the three common inherited bleeding disorders, the present study re-sequenced the exonic positions of F8, F9 and VWF using Ion Torrent sequencing based on an AmpliSeq strategy and made a quality assessment of the data obtained. To further validate the sequencing system a total of 24 subjects previously diagnosed with HA, HB or VWD were analyzed for their known mutations

Materials and methods

Results

Discussion