Nanopore sequencing and the Shasta toolkit enable efficient de novo assembly of eleven human genomes

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Shafin, Kishwar | Pesout, Trevor | Lorig-Roach, Ryan | Haukness, Marina | Olsen, Hugh | Bosworth, Colleen | Armstrong, Joel | Tigyi, Kristof | Maurer, Nicholas | Koren, Sergey | Sedlazeck, Fritz | Marschall, Tobias | Mayes, Simon | Costa, Vania | Zook, Justin | Liu, Kelvin | Kilburn, Duncan | Sorensen, Melanie | Munson, Katy | Vollger, Mitchell | Monlong, Jean | Garrison, Erik | Eichler, Evan | Salama, Sofie | Haussler, David | Green, Richard | Akeson, Mark | Phillippy, Adam | Miga, Karen | Carnevali, Paolo | Jain, Miten | Paten, Benedict

Edité par CCSD ; Nature Publishing Group -

International audience. Abstract De novo assembly of a human genome using nanopore long-read sequences has been reported, but it used more than 150,000 CPU hours and weeks of wall-clock time. To enable rapid human genome assembly, we present Shasta, a de novo long-read assembler, and polishing algorithms named MarginPolish and HELEN. Using a single PromethION nanopore sequencer and our toolkit, we assembled 11 highly contiguous human genomes de novo in 9 d. We achieved roughly 63× coverage, 42-kb read N50 values and 6.5× coverage in reads >100 kb using three flow cells per sample. Shasta produced a complete haploid human genome assembly in under 6 h on a single commercial compute node. MarginPolish and HELEN polished haploid assemblies to more than 99.9% identity (Phred quality score QV = 30) with nanopore reads alone. Addition of proximity-ligation sequencing enabled near chromosome-level scaffolds for all 11 genomes. We compare our assembly performance to existing methods for diploid, haploid and trio-binned human samples and report superior accuracy and speed.

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