Data from: DNA metabarcoding multiplexing and validation of data accuracy for diet assessment: application to omnivorous diet

Ecological understanding of the role of consumer-resource interactions in natural food webs is limited by the difficulty of accurately and efficiently determining the complex variety of food types animals have eaten in the field. We developed a method based on DNA metabarcoding multiplexing and next...

Full description

Bibliographic Details
Main Authors: De Barba, Marta, Miquel, Christian, Boyer, Frederic, Mercier, Céline, Rioux, Delphine, Coissac, Eric, Taberlet, Pierre
Format: Dataset
Language:unknown
Published: 2013
Subjects:
Diet Analysis
mitochondrial 16S gene
invertebrate DNA sequences
internal transcribed spacer
Asteraceae DNA sequences
vertebrate DNA sequences
Rosaceae DNA sequences
Illumina HiSeq 2000
Cyperaceae DNA sequences
mitochondrial 12S gene
consumer-resource interactions
Poaceae DNA sequences
internal controls
plant DNA sequences
mitochondrial 12S and 16S genes
Vertebrata
Ursus arctos
ITS 1
Arthropoda
ITS 2
Cyperaceae
chloroplast trnL (UAA)
Spermatophyta
Online Access:https://zenodo.org/record/4996578
https://doi.org/10.5061/dryad.1br2n
Description
Summary:Ecological understanding of the role of consumer-resource interactions in natural food webs is limited by the difficulty of accurately and efficiently determining the complex variety of food types animals have eaten in the field. We developed a method based on DNA metabarcoding multiplexing and next-generation sequencing to uncover different taxonomic groups of organisms from complex diet samples. We validated this approach on 91 faeces of a large omnivorous mammal, the brown bear, using DNA metabarcoding markers targeting the plant, vertebrate, and invertebrate components of the diet. We included internal controls in the experiments and performed PCR replication for accuracy validation in post-sequencing data analysis. Using our multiplexing strategy, we significantly simplified the experimental procedure and accurately and concurrently identified different prey DNA corresponding to the targeted taxonomic groups, with ≥60% of taxa of all diet components identified to genus/species level. The systematic application of internal controls and replication was a useful and simple way to evaluate the performance of our experimental procedure, standardize the selection of sequence filtering parameters for each marker data, and validate the accuracy of the results. Our general approach can be adapted to the analysis of dietary samples of various predator species in different ecosystems, for a number of conservation and ecological applications entailing large-scale population level diet assessment through cost effective screening of multiple DNA metabarcodes, and the detection of fine dietary variation among samples or individuals and of rare food items. GH_P3V5_P3MAV_P3Ast_P3Cyp_P3Poa_P3Ros_P3alignment_refDBcdSequence alignment of the chloroplast trnL (UAA) intron of 62 plantsalignment_refDBits2Sequence alignment of the internal transcribed spacer 2 (ITS2) of 30 plants of the family Rosaceae

Similar Items