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A Model and Simulation of the Influence of Temperature and Amplicon Length on Environmental DNA Degradation Rates: A Meta-Analysis Approach

Tatsuya Saito, Hideyuki Doi

2021Frontiers in Ecology and Evolution64 citationsDOIOpen Access PDF

Abstract

Environmental DNA (eDNA) analysis can detect aquatic organisms, including rare and endangered species, in a variety of habitats. Degradation can influence eDNA persistence, impacting eDNA-based species distribution and occurrence results. Previous studies have investigated degradation rates and associated contributing factors. It is important to integrate data from across these studies to better understand and synthesize eDNA degradation in various environments. We complied the eDNA degradation rates and related factors, especially water temperature and amplicon lengths of the measured DNA from 28 studies, and subjected the data to a meta-analysis. In agreement with previous studies, our results suggest that water temperature and amplicon length are significantly related to the eDNA degradation rate. From the 95% quantile model simulation, we predicted the maximum eDNA degradation rate in various combinations of water temperature and amplicon length. Predicting eDNA degradation could be important for evaluating species distribution and inducing innovation (e.g., sampling, extraction, and analysis) of eDNA methods, especially for rare and endangered species with small population size.

Topics & Concepts

Environmental DNAEndangered speciesAmpliconDegradation (telecommunications)Habitat destructionBiologyEcologyEnvironmental scienceHabitatBiodiversityPolymerase chain reactionGeneticsComputer scienceGeneTelecommunicationsEnvironmental DNA in Biodiversity StudiesMicrobial Community Ecology and PhysiologyIdentification and Quantification in Food
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