Genotype Hemophilia Screening Program Identified 2 Novel Variants Including a Novel Variant (c.5816-2A > G) Causing a Pathogenic Variant of the Factor 8 Gene.

Establishing a national screening program for hemophilia patients is highly encouraged by the World Health Organization and the World Federation of Hemophilia. Hence, this study aimed to analyze the variant spectrum of F8 and F9 genes in Arab hemophilia patients. Molecular genetic and sequencing studies were performed on a cohort of 135 Saudi hemophilia patients. Out of all screened hemophilia patients (97 hemophilia A and 39 hemophilia B), 15 (11.1%) were positive for inversion 22 and 4 (3%) for inversion 1. Out of a total of 32 (23.7%) substitution/deletion mutations, 2 novel variants were identified: a novel splice acceptor site missense mutation (c.5816-2A > G) causing a pathogenic variant of the F8 gene and another splicing site point mutation in intron/exon 23 (g.164496G > A). The frequent F8 variants were (c.409A > C, p.T137P) in exon 4, (c.760A > G) in exon 6, and (c.1835G > C, p.R612P) in exon 12, while the frequent F9 variants were (c.580A > G) in exon 6 and (c.880C > T) in exon 8. These study data will enrich the spectrum of the genetic databases in the Arab population that could be applied in the future for national genetic counseling.

Molecular yield of targeted sequencing for Glanzmann thrombasthenia patients.

Glanzmann thrombasthenia (GT) is a rare autosomal recessive bleeding disorder. Around 490 mutations in ITGA2B and ITGB3 genes were reported. We aimed to use targeted next-generation sequencing (NGS) to identify variants in patients with GT. We screened 72 individuals (including unaffected family members) using a panel of 393 genes (SHGP heme panel). Validation was done by Sanger sequencing and pathogenicity was predicted using multiple tools. In 83.5% of our cohort, 17 mutations were identified in ITGA2B and ITGB3 (including 6 that were not previously reported). In addition to variants in the two known genes, we found variants in ITGA2, VWF and F8. The SHGP heme panel can be used as a high-throughput molecular diagnostic assay to screen for mutations and variants in GT cases and carriers. Our findings expand the molecular landscape of GT and emphasize the robustness and usefulness of this panel.