Abstract
Following a nanopore sequencing run of PCR products of three amplicons less than 1kb, an abundance of reads failed quality control due to template/complement mismatch. A BLAST search demonstrated that some of the failed reads mapped to two different genes -- an unexpected observation, given that PCR was carried out separately for each amplicon. A further investigation was carried out specifically to search for chimeric reads, using separate barcodes for each amplicon and trying two different ligation methods prior to sample loading. Despite the separation of ligation products, chimeric reads formed from different amplicons were still observed in the base-called sequence.The long-read nature of nanopore sequencing presents an effective tool for the discovery and filtering of chimeric reads. We have found that at least 1.7% of reads prepared using the Nanopore LSK002 2D Ligation Kit include post-amplification chimeric elements. This finding has potential implications for other amplicon sequencing technologies, as the process is unlikely to be specific to the sample preparation used for nanopore sequencing.
Highlights
High-throughput DNA sequencing is a rapidly evolving field with new methods and applications introduced almost weekly[1]
The MinION has been used for cDNA sequencing[13], for detecting DNA methylation patterns without chemical treatment[8,14], and for direct RNA sequencing with detection of modified 16S rRNA nucleotides[15]
Using the most recent R9.4 flow cells, we have evaluated the MinION technology for the amplicon sequencing of highly similar genes
Summary
High-throughput DNA sequencing is a rapidly evolving field with new methods and applications introduced almost weekly[1]. One of the most recent sequencing technologies available on the market is the MinION sequencing device from Oxford Nanopore Technologies (ONT)[2]. The advantages of the MinION are rapid library preparation, portability[5,6], long molecule sequencing[7], and sequencing of non-model modifications of the DNA strand[8]. With the recent improvement in the chemistry of the MinION, ONT has overcome the majority of issues associated with low yield and high error rates that have limited the range of its application. The MinION sequencing device has been successfully applied to sequence genomes of a wide range of sizes, from bacterial and viral genomes[9,10], amplicon sequencing like bacterial 16S rRNA sequencing[11], and more recently a human genome[12]. The MinION has been used for cDNA sequencing[13], for detecting DNA methylation patterns without chemical treatment[8,14], and for direct RNA sequencing with detection of modified 16S rRNA nucleotides[15]
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