Abstract
Somatic activating GNAS mutations cause McCune-Albright syndrome (MAS). Owing to low mutation abundance, mutant-specific enrichment procedures, such as the peptide nucleic acid (PNA) method, are required to detect mutations in peripheral blood. Next generation sequencing (NGS) can analyze millions of PCR amplicons independently, thus it is expected to detect low-abundance GNAS mutations quantitatively. In the present study, we aimed to develop an NGS-based method to detect low-abundance somatic GNAS mutations. PCR amplicons encompassing exons 8 and 9 of GNAS, in which most activating mutations occur, were sequenced on the MiSeq instrument. As expected, our NGS-based method could sequence the GNAS locus with very high read depth (approximately 100,000) and low error rate. A serial dilution study with use of cloned mutant and wildtype DNA samples showed a linear correlation between dilution and measured mutation abundance, indicating the reliability of quantification of the mutation. Using the serially diluted samples, the detection limits of three mutation detection methods (the PNA method, NGS, and combinatory use of PNA and NGS [PNA-NGS]) were determined. The lowest detectable mutation abundance was 1% for the PNA method, 0.03% for NGS and 0.01% for PNA-NGS. Finally, we analyzed 16 MAS patient-derived leukocytic DNA samples with the three methods, and compared the mutation detection rate of them. Mutation detection rate of the PNA method, NGS and PNA-NGS in 16 patient-derived peripheral blood samples were 56%, 63% and 75%, respectively. In conclusion, NGS can detect somatic activating GNAS mutations quantitatively and sensitively from peripheral blood samples. At present, the PNA-NGS method is likely the most sensitive method to detect low-abundance GNAS mutation.
Highlights
The rapid emergence of generation sequencing (NGS) is revolutionizing medical sciences
GNAS amplicon sequencing by next generation sequencing (NGS) We designed chimeric primer pairs, containing both locusspecific and adapter sequences, to generate PCR amplicons that are directly sequenced on the Illumina MiSeq platform
Quantitative detection of a GNAS mutation To test the ability of the NGS-based mutation detection to provide quantitative data, we conducted a serial dilution study using cloned plasmid DNA samples
Summary
The rapid emergence of generation sequencing (NGS) is revolutionizing medical sciences. NGS allows clinical investigators to analyze transcriptome, exome and genome from small amounts of DNA/RNA. NGS is available for ultra-deep sequencing of PCR amplicons, microRNA and microbiomes. NGS-based approaches have brought remarkable advances in a broad range of medical research areas, such as studies of rare Mendelian disorders [1] and surveillance of infectious disease outbreaks [2]. NGS has provided a wealth of new information for cancer genomics, owing in part to the ultra-deep amplicon sequencing of cancerous and precancerous cells [3]. Because NGS can analyze millions of DNA fragments simultaneously and independently, low abundance mutations of oncogenes have become readily detectable. In contrast to advances in understanding of somatic mutations associated with cancer, knowledge about somatic mutations causing benign congenital disorders remains very limited
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