2019
DOI: 10.1186/s12864-019-6337-2
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LRScaf: improving draft genomes using long noisy reads

Abstract: BackgroundThe advent of third-generation sequencing (TGS) technologies opens the door to improve genome assembly. Long reads are promising for enhancing the quality of fragmented draft assemblies constructed from next-generation sequencing (NGS) technologies. To date, a few algorithms that are capable of improving draft assemblies have released. There are SSPACE-LongRead, OPERA-LG, SMIS, npScarf, DBG2OLC, Unicycler, and LINKS. Hybrid assembly on large genomes remains challenging, however.ResultsWe develop a sc… Show more

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Cited by 62 publications
(41 citation statements)
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“…The polished assembly was broken into contigs using split.scaffolds.to.contigs.pl ( https://github.com/MadsAlbertsen/miscperlscripts/blob/master/split.scaffolds.to.contigs.pl ). The broken contigs were subjected to the first round of iterative scaffolding by the following programs: LRScaf v1.1.11 ( Qin et al 2019 ), using ONT long reads; BESST v2.2.8 ( Sahlin et al 2014 ), using Illumina mate-pair reads from all libraries; L_RNA_Scaffolder, using the transcriptome shotgun assembly and Iso-Seq cDNA sequences (aligned by BLAT v36). Each scaffolding was followed by gap-filling by TGS-GapCloser v1.1.1 and polishing by NtEdit v1.3.2.…”
Section: Methodsmentioning
confidence: 99%
“…The polished assembly was broken into contigs using split.scaffolds.to.contigs.pl ( https://github.com/MadsAlbertsen/miscperlscripts/blob/master/split.scaffolds.to.contigs.pl ). The broken contigs were subjected to the first round of iterative scaffolding by the following programs: LRScaf v1.1.11 ( Qin et al 2019 ), using ONT long reads; BESST v2.2.8 ( Sahlin et al 2014 ), using Illumina mate-pair reads from all libraries; L_RNA_Scaffolder, using the transcriptome shotgun assembly and Iso-Seq cDNA sequences (aligned by BLAT v36). Each scaffolding was followed by gap-filling by TGS-GapCloser v1.1.1 and polishing by NtEdit v1.3.2.…”
Section: Methodsmentioning
confidence: 99%
“…The purged genome underwent further scaffolding and gap-closing steps using Rails (v.1.5.1) and Cobbler (v.0.6.1) (Warren 2016), Lrscaf (v.1.1.11) (Qin et al . 2019) and Lrgapcloser (Xu et al .…”
Section: Methodsmentioning
confidence: 99%
“…LoRMA [150], NaS [151], proovread [152] Long reads Canu [114], CONSENT [153], Daccord [154], FLAS [155], HALC [156], NextDenovo [121], MECAT [118], MECAT2 [118], NECAT [120] Polishing Short reads ntEdit [157], Pilon [158], POLCA [159] Short & long reads Apollo [160], Hapo-G [161], HyPo [162], Racon [163] Nanopolish [164], Quiver [165] Haplotig purging Long reads HaploMerger2 [166], purge dups [167], Purge Haplotigs [168] Scaffolding Short reads Bambus [169], BATISCAF [170], BESST [171], BOSS [172], Mate pairs GRASS [173], MIP [174], Opera [175], ScaffMatch [176], ScaffoldScaffolder [177], SCARPA [178], SCOP [179], SLIQ [180], SOPRA [181], SSPACE [182], WiseScaffolder [183] Long reads DENTIST [184], LINKS [185], LRScaf [186], npScarf [187], PBJelly [188], RAILS [189], SLR [190],...…”
Section: Assembly Pre and Post-processingmentioning
confidence: 99%