Enrichment of megabase-sized DNA molecules for single-molecule optical mapping and next-generation sequencing

Joanna M Łopacińska-Jørgensen,Rafael J Taboryski,Rodolphe Marie,Henrik Flyvbjerg,Jonas N Pedersen,Mana M Mehrjouy,Brian Bilenberg,Kristian T Sørensen,Mads Bak,Anders Kristensen,Niels Tommerup,Peter F Østergaard,Asli Silahtaroglu

doi:10.1038/s41598-017-18091-6

Joanna M Łopacińska-Jørgensen, Rafael J Taboryski + Show 11 more

Open Access

https://doi.org/10.1038/s41598-017-18091-6

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Abstract

Next-generation sequencing (NGS) has caused a revolution, yet left a gap: long-range genetic information from native, non-amplified DNA fragments is unavailable. It might be obtained by optical mapping of megabase-sized DNA molecules. Frequently only a specific genomic region is of interest, so here we introduce a method for selection and enrichment of megabase-sized DNA molecules intended for single-molecule optical mapping: DNA from a human cell line is digested by the NotI rare-cutting enzyme and size-selected by pulsed-field gel electrophoresis. For demonstration, more than 600 sub-megabase- to megabase-sized DNA molecules were recovered from the gel and analysed by denaturation-renaturation optical mapping. Size-selected molecules from the same gel were sequenced by NGS. The optically mapped molecules and the NGS reads showed enrichment from regions defined by NotI restriction sites. We demonstrate that the unannotated genome can be characterized in a locus-specific manner via molecules partially overlapping with the annotated genome. The method is a promising tool for investigation of structural variants in enriched human genomic regions for both research and diagnostic purposes. Our enrichment method could potentially work with other genomes or target specified regions by applying other genomic editing tools, such as the CRISPR/Cas9 system.

Highlights

IntroductionTermed reduced representation, are commonly used in NGS workflows to enrich for subsets of the genome before sequencing[17]
Methods of target enrichment, termed reduced representation, are commonly used in NGS workflows to enrich for subsets of the genome before sequencing[17]
Size selected DNA from the same pulsed-field gel electrophoresis (PFGE) gels were analysed by single-molecule optical mapping to demonstrate that the method produced long, intact DNA molecules from regions specified by NotI-cutting

Summary

Introduction

Termed reduced representation, are commonly used in NGS workflows to enrich for subsets of the genome before sequencing[17]. None of the existing target enrichment methods, commonly used in NGS workflows[17,22,23] could be combined with subsequent optical mapping, since fragmentation of the target sequence to less than 5 kilobasepairs (kb) pieces is a key step for preparing DNA for any NGS analysis[24]. We hereby enrich for megabase-sized single DNA molecules from specified human genomic regions for optical mapping in nanodevices and NGS. Size selected DNA from the same PFGE gels were analysed by single-molecule optical mapping to demonstrate that the method produced long, intact DNA molecules from regions specified by NotI-cutting. Our enrichment method increases the efficiency of DR mapping and lowers the need for high throughput

Methods

Results

Conclusion