000 02317 am a22002653u 4500
042 _adc
100 1 0 _aContreras-Moreira, Bruno
_eauthor
700 1 0 _aFilippi, Carla V
_eauthor
_93003
700 1 0 _aNaamati, Guy
_eauthor
700 1 0 _aGirón, Carlos García
_eauthor
_93005
700 1 0 _aAllen, James E
_eauthor
700 1 0 _aFlicek, Paul
_eauthor
245 0 0 _aK-mer counting and curated libraries drive efficient annotation of repeats in plant genomes
260 _c2021-11-01.
500 _a/pmc/articles/PMC7614178/
500 _a/pubmed/34562304
520 _aThe annotation of repetitive sequences within plant genomes can help in the interpretation of observed phenotypes. Moreover, repeat masking is required for tasks such as whole-genome alignment, promoter analysis, or pangenome exploration. Although homology-based annotation methods are computationally expensive, k-mer strategies for masking are orders of magnitude faster. Here, we benchmarked a two-step approach, where repeats were first called by k-mer counting and then annotated by comparison to curated libraries. This hybrid protocol was tested on 20 plant genomes from Ensembl, with the k-mer-based Repeat Detector (Red) and two repeat libraries (REdat, last updated in 2013, and nrTEplants, curated for this work). Custom libraries produced by RepeatModeler were also tested. We obtained repeated genome fractions that matched those reported in the literature but with shorter repeated elements than those produced directly by sequence homology. Inspection of the masked regions that overlapped genes revealed no preference for specific protein domains. Most Red-masked sequences could be successfully classified by sequence similarity, with the complete protocol taking less than 2 h on a desktop Linux box. A guide to curating your own repeat libraries and the scripts for masking and annotating plant genomes can be obtained at https://github.com/Ensembl/plant-scripts.
540 _a
540 _ahttps://creativecommons.org/licenses/by/4.0/This work is licensed under a CC BY 4.0 (https://creativecommons.org/licenses/by/4.0/) International license.
546 _aen
690 _aArticle
655 7 _aText
_2local
786 0 _nPlant Genome
856 4 1 _uhttp://dx.doi.org/10.1002/tpg2.20143
_zConnect to this object online.
999 _c2397
_d2397