Litcius/Paper detail

Inpactor2: a software based on deep learning to identify and classify LTR-retrotransposons in plant genomes

Simón Orozco-Arias, Luis Humberto López-Murillo, Mariana S. Candamil-Cortés, Maradey Arias, Paula A. Jaimes, Alexandre Rossi Paschoal, Reinel Tabares-Soto, Gustavo Isaza, Romain Guyot

2022Briefings in Bioinformatics28 citationsDOIOpen Access PDF

Abstract

LTR-retrotransposons are the most abundant repeat sequences in plant genomes and play an important role in evolution and biodiversity. Their characterization is of great importance to understand their dynamics. However, the identification and classification of these elements remains a challenge today. Moreover, current software can be relatively slow (from hours to days), sometimes involve a lot of manual work and do not reach satisfactory levels in terms of precision and sensitivity. Here we present Inpactor2, an accurate and fast application that creates LTR-retrotransposon reference libraries in a very short time. Inpactor2 takes an assembled genome as input and follows a hybrid approach (deep learning and structure-based) to detect elements, filter partial sequences and finally classify intact sequences into superfamilies and, as very few tools do, into lineages. This tool takes advantage of multi-core and GPU architectures to decrease execution times. Using the rice genome, Inpactor2 showed a run time of 5 minutes (faster than other tools) and has the best accuracy and F1-Score of the tools tested here, also having the second best accuracy and specificity only surpassed by EDTA, but achieving 28% higher sensitivity. For large genomes, Inpactor2 is up to seven times faster than other available bioinformatics tools.

Topics & Concepts

RetrotransposonGenomeIdentification (biology)Computer scienceSoftwareComputational biologyArtificial intelligenceBiologyMachine learningTransposable elementGeneticsGeneProgramming languageBotanyChromosomal and Genetic VariationsGenomics and Phylogenetic StudiesPlant Virus Research Studies