Singleton mutations in large-scale cancer genome studies: uncovering the tail of cancer genome.
Sanket DesaiSuhail AhmadBhargavi BawaskarSonal RashmiRohit MishraDeepika LakhwaniAmit DuttPublished in: NAR cancer (2024)
Singleton or low-frequency driver mutations are challenging to identify. We present a domain driver mutation estimator (DOME) to identify rare candidate driver mutations. DOME analyzes positions analogous to known statistical hotspots and resistant mutations in combination with their functional and biochemical residue context as determined by protein structures and somatic mutation propensity within conserved PFAM domains, integrating the CADD scoring scheme. Benchmarked against seven other tools, DOME exhibited superior or comparable accuracy compared to all evaluated tools in the prediction of functional cancer drivers, with the exception of one tool. DOME identified a unique set of 32 917 high-confidence predicted driver mutations from the analysis of whole proteome missense variants within domain boundaries across 1331 genes, including 1192 noncancer gene census genes, emphasizing its unique place in cancer genome analysis. Additionally, analysis of 8799 TCGA (The Cancer Genome Atlas) and in-house tumor samples revealed 847 potential driver mutations, with mutations in tyrosine kinase members forming the dominant burden, underscoring its higher significance in cancer. Overall, DOME complements current approaches for identifying novel, low-frequency drivers and resistant mutations in personalized therapy.
Keyphrases
- papillary thyroid
- squamous cell
- genome wide
- tyrosine kinase
- copy number
- gene expression
- lymph node metastasis
- epidermal growth factor receptor
- dna methylation
- squamous cell carcinoma
- high resolution
- mesenchymal stem cells
- mass spectrometry
- autism spectrum disorder
- young adults
- childhood cancer
- weight loss
- gestational age