Modified SureSelectQXT Target Enrichment Protocol for Illumina Multiplexed Sequencing of FFPE Samples

Background Personalised medicine is nowadays a major objective in oncology. Molecular characterization of tumours through NGS offers the possibility to find possible therapeutic targets in a time- and cost-effective way. However, the low quality and complexity of FFPE DNA samples bring a series of d...

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Published inBiological procedures online Vol. 20; no. 1; p. 19
Main Authors Rosa-Rosa, J. M, Caniego-Casas, T, Leskela, S, Muéoz, G, del Castillo, F, Garrido, P, Palacios, J
Format Journal Article
LanguageEnglish
Published London BioMed Central Ltd 12.10.2018
BioMed Central
Subjects
Cancer
Cell culture
Deoxyribonucleic acid
DNA
DNA sequencing
Enzymes
Experiments
Genetic testing
Methodology
Mutation
Oncology
Protocol
Quality standards
Tumors
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Summary:Background Personalised medicine is nowadays a major objective in oncology. Molecular characterization of tumours through NGS offers the possibility to find possible therapeutic targets in a time- and cost-effective way. However, the low quality and complexity of FFPE DNA samples bring a series of disadvantages for massive parallel sequencing techniques compared to high-quality DNA samples (from blood cells, cell cultures, etc.). Results We performed several experiments to understand the behaviour of FFPE DNA samples during the construction of SureSelect.sup.QXT libraries. First, we designed a quality checkpoint for FFPE DNA samples based on the quantification of their amplification capability (qcPCR). We observed that FFPE DNA samples can be classified according to DIN value and qcPCR concentration into unusable, or low-quality (LQ) and good-quality (GQ) DNA. For GQ samples, we increased the amount of input DNA to 150 ng and the digestion time to 30 min, whereas for LQ samples, we used 50 ng of DNA as input but we decreased the digestion time to 1 min. In all cases, we increased the cycles of the pre-hyb PCR to 10 but decreased the cycles of the post-hyb PCR to 8. In addition, we confirmed that using half of the volume of reagents can be beneficial. Finally, in order to obtain better results, we designed a decision flow-chart to achieve a seeding concentration of 12-14 pM for MiSeq Reagent Kit v2. Conclusions Our experiments allowed us to unveil the behaviour of low-quality FFPE DNA samples during the construction of SureSelect.sup.QXT libraries. Sequencing results showed that, using our modified SureSelect.sup.QXT protocol, the final percentage of usable reads for low-quality samples was increased more than three times allowing to reach median depth/million reads values of 76.35. This value is equivalent to ~ 0.9 and ~ 0.7 of the values obtained for good-quality FFPE and high-quality DNA respectively. Keywords: NGS, FFPE samples, SureSelect.sup.QXT, Optimization, Protocol
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ISSN:1480-9222
1480-9222
DOI:10.1186/s12575-018-0084-7