An efficient molecular genetic testing strategy for incontinentia pigmenti based on single-tube long fragment read sequencing.
Min ChenMei-Hua TanJiao LiuYan-Mei YangJia-Ling YuLi-Juan HeYing-Zhi HuangYi-Xi SunYe-Qing QianKai YanMin-Yue DongPublished in: NPJ genomic medicine (2024)
Incontinentia pigmenti (IP) is a rare X-linked dominant neuroectodermal dysplasia that primarily affects females. The only known causative gene is IKBKG, and the most common genetic cause is the recurrent IKBKG △4-10 deletion resulting from recombination between two MER67B repeats. Detection of variants in IKBKG is challenging due to the presence of a highly homologous non-pathogenic pseudogene IKBKGP1. In this study, we successfully identified four pathogenic variants in four IP patients using a strategy based on single-tube long fragment read (stLFR) sequencing with a specialized analysis pipeline. Three frameshift variants (c.519-3_519dupCAGG, c.1167dupC, and c.700dupT) were identified and subsequently validated by Sanger sequencing. Notably, c.519-3_519dupCAGG was found in both IKBKG and IKBKGP1, whereas the other two variants were only detected in the functional gene. The IKBKG △4-10 deletion was identified and confirmed in one patient. These results demonstrate that the proposed strategy can identify potential pathogenic variants and distinguish whether they are derived from IKBKG or its pseudogene. Thus, this strategy can be an efficient genetic testing method for IKBKG. By providing a comprehensive understanding of the whole genome, it may also enable the exploration of other genes potentially associated with IP. Furthermore, the strategy may also provide insights into other diseases with detection challenges due to pseudogenes.
Keyphrases
- copy number
- genome wide
- single cell
- dna methylation
- single molecule
- ejection fraction
- end stage renal disease
- dna damage
- newly diagnosed
- gene expression
- genome wide identification
- case report
- palliative care
- peritoneal dialysis
- risk assessment
- prognostic factors
- loop mediated isothermal amplification
- sensitive detection
- patient reported outcomes
- climate change