Shrestha A.M.S, Gonzales M.E.M., Ong P.C.L., Larmande Pierre, Lee H.S., Jeung J.U., Kohli A., Chebotarov D., Mauleon R.P., Lee J.S., McNally K.L. (2024). RicePilaf : a post-GWAS/QTL dashboard to integrate pangenomic, coexpression, regulatory, epigenomic, ontology, pathway, and text-mining information to provide functional insights into rice QTLs and GWAS loci. GigaScience, 13, giae013 [12 p.]. ISSN 2047-217X.
Titre du document
RicePilaf : a post-GWAS/QTL dashboard to integrate pangenomic, coexpression, regulatory, epigenomic, ontology, pathway, and text-mining information to provide functional insights into rice QTLs and GWAS loci
Année de publication
2024
Auteurs
Shrestha A.M.S, Gonzales M.E.M., Ong P.C.L., Larmande Pierre, Lee H.S., Jeung J.U., Kohli A., Chebotarov D., Mauleon R.P., Lee J.S., McNally K.L.
Source
GigaScience, 2024,
13, giae013 [12 p.] ISSN 2047-217X
Background : As the number of genome-wide association study (GWAS) and quantitative trait locus (QTL) mappings in rice continues to grow, so does the already long list of genomic loci associated with important agronomic traits. Typically, loci implicated by GWAS/QTL analysis contain tens to hundreds to thousands of single-nucleotide polmorphisms
(SNPs)/genes, not all of which are causal and many of which are in noncoding regions. Unraveling the biological mechanisms that tie the GWAS regions and QTLs to the trait of interest is challenging, especially since it requires collating functional genomics information about the loci from multiple, disparate data sources.
Results : We present RicePilaf, a web app for post-GWAS/QTL analysis, that performs a slew of novel bioinformatics analyses to cross-reference GWAS results and QTL mappings with a host of publicly available rice databases. In particular, it integrates (i) pangenomic information from high-quality genome builds of multiple rice varieties, (ii) coexpression information from genome-scale coexpression networks, (iii) ontology and pathway information, (iv) regulatory information from rice transcription factor databases, (v) epigenomic information from multiple high-throughput epigenetic experiments, and (vi) text-mining information extracted from scientific abstracts linking genes and traits. We demonstrate the utility of RicePilaf by applying it to analyze GWAS peaks of preharvest sprouting and genes underlying yield-under-drought QTLs.
Conclusions : RicePilaf enables rice scientists and breeders to shed functional light on their GWAS regions and QTLs, and it provides them with a means to prioritize SNPs/genes for further experiments. The source code, a Docker image, and a demo version of RicePilaf are publicly available at https://github.com/bioinfodlsu/rice-pilaf.
Plan de classement
Amélioration des plantes, ressources génétiques [076AMEPLA]
Localisation
Fonds IRD [F B010091456]
Identifiant IRD
fdi:010091456
