Abstract
AbstractNanopore sequencing technology has revolutionized the field of genome biology with its ability to generate extra-long reads that can resolve regions of the genome that were previously inaccessible to short-read sequencing platforms. Although long-read sequencing has been used to resolve several vertebrate genomes, a nanopore-based zebrafish assembly has not yet been released. Over 50% of the zebrafish genome consists of difficult to map, highly repetitive, low complexity elements that pose inherent problems for short-read sequencers and assemblers. We used nanopore sequencing to improve upon and resolve the issues plaguing the current zebrafish reference assembly (GRCz11). Our long-read assembly improved the current resolution of the reference genome by identifying 1,697 novel insertions and deletions over 1Kb in length and placing 106 previously unlocalized scaffolds. We also discovered additional sites of retrotransposon integration previously unreported in GRCz11 and observed their expression in adult zebrafish under physiologic conditions, implying they have active mobility in the zebrafish genome and contribute to the ever-changing genomic landscape.
Publisher
Cold Spring Harbor Laboratory
Reference40 articles.
1. Zebrafish
hox
Clusters and Vertebrate Genome Evolution
2. Behaviour of Telomere and Telomerase during Aging and Regeneration in Zebrafish
3. Effects of Chloramphenicol on the Development of the Zebrafish, Brachydanio Rerio;Canadian Journal of Zoology,1967
4. Next-Generation Sequencing Technologies and Their Application to the Study and Control of Bacterial Infections;Clinical Microbiology and Infection : The Official Publication of the European Society of Clinical Microbiology and Infectious Diseases,2018
5. D-GENIES: dot plot large genomes in an interactive, efficient and simple way