A progeroid syndrome caused by a deep intronic variant in TAPT1 is revealed by RNA/SI-NET sequencing.
Nasrinsadat NabavizadehAnnkatrin BressinMohammad ShboulRicardo Moreno TraspasPoh Hui ChiaCarine BonnardEmmanuelle Szenker-RaviBurak SarıbaşEmmanuel BeillardUmut AltunogluZohreh HojatiScott DrutmanSusanne FreierMohammad El-KhateebRajaa FathallahJean-Laurent CasanovaWesam SororAlaa ArafatNathalie Escande-BeillardAndreas MayerBruno ReversadePublished in: EMBO molecular medicine (2023)
Exome sequencing has introduced a paradigm shift for the identification of germline variations responsible for Mendelian diseases. However, non-coding regions, which make up 98% of the genome, cannot be captured. The lack of functional annotation for intronic and intergenic variants makes RNA-seq a powerful companion diagnostic. Here, we illustrate this point by identifying six patients with a recessive Osteogenesis Imperfecta (OI) and neonatal progeria syndrome. By integrating homozygosity mapping and RNA-seq, we delineated a deep intronic TAPT1 mutation (c.1237-52 G>A) that segregated with the disease. Using SI-NET-seq, we document that TAPT1's nascent transcription was not affected in patients' fibroblasts, indicating instead that this variant leads to an alteration of pre-mRNA processing. Predicted to serve as an alternative splicing branchpoint, this mutation enhances TAPT1 exon 12 skipping, creating a protein-null allele. Additionally, our study reveals dysregulation of pathways involved in collagen and extracellular matrix biology in disease-relevant cells. Overall, our work highlights the power of transcriptomic approaches in deciphering the repercussions of non-coding variants, as well as in illuminating the molecular mechanisms of human diseases.
Keyphrases
- rna seq
- single cell
- extracellular matrix
- copy number
- end stage renal disease
- ejection fraction
- chronic kidney disease
- induced apoptosis
- endothelial cells
- newly diagnosed
- room temperature
- peritoneal dialysis
- cell cycle arrest
- case report
- binding protein
- dna damage
- transcription factor
- dna repair
- oxidative stress
- gene expression
- high density
- small molecule
- pi k akt
- duchenne muscular dystrophy