Keyword search (4,163 papers available)

"Yates MC" Authored Publications:

Title Authors PubMed ID
1 eDNA Provides Accurate Population Abundance Estimates With Bioenergetics and Particle Mass-Balance Modelling Beaulieu J; Yates MC; Fraser DJ; Cristescu ME; Derry AM; 41913704
BIOLOGY
2 Evaluating the correlation between genome-wide diversity and the release of plastic phenotypic variation in experimental translocations to novel natural environments. Yates MC, Fraser DJ 33274531
BIOLOGY
3 The relationship between eDNA particle concentration and organism abundance in nature is strengthened by allometric scaling. Yates MC, Glaser D, Post J, Cristescu ME, Fraser DJ, Derry AM 32638451
CONCORDIA
4 Small population size and low genomic diversity have no effect on fitness in experimental translocations of a wild fish. Yates MC, Bowles E, Fraser DJ 31771476
BIOLOGY
5 A critical assessment of estimating census population size from genetic population size (or vice versa) in three fishes. Yates MC, Bernos TA, Fraser DJ 29151884
BIOLOGY

 

Title:The relationship between eDNA particle concentration and organism abundance in nature is strengthened by allometric scaling.
Authors:Yates MCGlaser DPost JCristescu MEFraser DJDerry AM
Link:https://www.ncbi.nlm.nih.gov/pubmed/32638451?dopt=Abstract
DOI:10.1111/mec.15543
Publication:Molecular ecology
Keywords:abundanceallometric scalingallometrybiomassdensityeDNAenvironmental DNA
PMID:32638451 Category:Mol Ecol Date Added:2020-07-09
Dept Affiliation: CONCORDIA
1 Université du Québec à Montréal, Montréal, Québec, Canada.
2 University of Calgary Calgary, Alberta, Canada.
3 McGill University Montreal, Quebec, Canada.
4 Concordia University Montreal, Quebec, Canada.

Description:

The relationship between eDNA particle concentration and organism abundance in nature is strengthened by allometric scaling.

Mol Ecol. 2020 Jul 07;:

Authors: Yates MC, Glaser D, Post J, Cristescu ME, Fraser DJ, Derry AM

Abstract

Organism abundance is a critical parameter in ecology, but its estimation is often challenging. Approaches utilizing eDNA to indirectly estimate abundance have recently generated substantial interest. However, preliminary correlations observed between eDNA concentration and abundance in nature are typically moderate in strength with significant unexplained variation. Here we apply a novel approach to integrate allometric scaling coefficients into models of eDNA concentration and organism abundance. We hypothesize that eDNA particle production scales non-linearly with mass, with scaling coefficients < 1. Wild populations often exhibit substantial variation in individual body size distributions; we therefore predict that the distribution of mass across individuals within a population will influence population-level eDNA production rates. To test our hypothesis, we collected standardized body size distribution and mark-recapture abundance data using whole-lake experiments involving nine populations of brook trout. We correlated eDNA concentration with three metrics of abundance: density (individuals/ha), biomass (kg/ha), and allometrically scaled mass (ASM) (?(individual mass0.73 )/ha). Density and biomass were both significantly positively correlated with eDNA concentration (adj. r2 = 0.59 and 0.63, respectively), but ASM exhibited improved model fit (adj. r2 = 0.78). We also demonstrate how estimates of ASM derived from eDNA samples in 'unknown' systems can be converted to biomass or density estimates with additional size structure data. Future experiments should empirically validate allometric scaling coefficients for eDNA production, particularly where substantial intraspecific size distribution variation exists. Incorporating allometric scaling may improve predictive models to the extent that eDNA concentration may become a reliable indicator of abundance in nature.

PMID: 32638451 [PubMed - as supplied by publisher]




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