Abstract
Long‐read sequencing can resolve regions of the genome that are inaccessible to short reads, and therefore are ideal for genome‐gap closure, solving structural rearrangements and sequencing through repetitive elements. Here we introduce the Xdrop technology: a novel microfluidic‐based system that allows for targeted enrichment of long DNA molecules starting from only a few nanograms of DNA. Xdrop is based on the isolation of long DNA fragments in millions of droplets, where the droplets containing a target sequence of interest are fluorescently labeled and sorted using flow cytometry. The final product from the Xdrop procedure is an enriched population of long DNA molecules that can be investigated by sequencing. To demonstrate the capability of Xdrop, we performed enrichment of the human papilloma virus 18 integrated into the genome of human HeLa cells. Analysis of the sequencing reads resolved three HPV18‐chr8 integrations at base‐pair resolution, and the captured fragments extended up to 30 kb into the human genome at the integration sites. Further, we enriched the complete TP53 locus in a leukemia cell line and could successfully phase coexisting mutations using PacBio sequencing. In summary, our results show that Xdrop is an efficient enrichment technology for studying complex genomic regions.
Highlights
Long‐read sequencing can resolve regions of the genome that are inaccessible to short reads, and are ideal for genome‐gap closure, solving structural rearrangements and sequencing through repetitive elements
We further demonstrated the utility of this technology by enriching for the cancer suppressor gene TP53 in a human leukemia cancer cell line, allowing for detection and phasing of mutations
The Xdrop technology is based on the generation of millions of double emulsion (DE) water‐in‐oil‐in‐water droplets with an inner diameter of 15 μm and outer diameter of 20 μm, that is in the same size‐range as large eukaryotic cells
Summary
Hybridization‐based methods can enrich for fragments up to 10 kb based on the information of a short probe (500 ng) Both long‐range PCR and hybridization methods have a risk of introducing chimeric reads during amplification steps in the sample or library preparation. The Xdrop system permits the enriched DNA to be sequenced on a long‐read sequencing platform, such as PacBio or ONT, or alternatively to provide long‐fragment information from short‐ read sequencing. ~150 bases of sequence information are needed to perform enrichment of DNA fragments of up to 40 kb in size, and the protocol requires as little as 1–2 ng of DNA as input to enrich for a specific region in a human‐sized genome. We further demonstrated the utility of this technology by enriching for the cancer suppressor gene TP53 in a human leukemia cancer cell line, allowing for detection and phasing of mutations
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