Particle size distribution and optimal capture of aqueous macrobial eDNA

Summary

Summary 1. Using environmental DNA (eDNA) to detect aquatic macroorganisms is a new survey method with broad applicability. However, the origin, state and fate of aqueous macrobial eDNA – which collectively determine how well eDNA can serve as a proxy for directly observing organisms and how eDNA should be captured, purified and assayed – are poorly understood. 2. The size of aquatic particles provides clues about their origin, state and fate. We used sequential filtration size fractionation to measure the particle size distribution (PSD) of macrobial eDNA, specifically Common Carp (hereafter referred to as Carp) eDNA. We compared it to the PSDs of total eDNA (from all organisms) and suspended particle matter (SPM). We quantified Carp [...]

Summary

Summary
1. Using environmental DNA (eDNA) to detect aquatic macroorganisms is a new survey method with broad
applicability. However, the origin, state and fate of aqueous macrobial eDNA – which collectively determine
how well eDNA can serve as a proxy for directly observing organisms and how eDNA should be captured,
purified and assayed – are poorly understood.
2. The size of aquatic particles provides clues about their origin, state and fate. We used sequential filtration size
fractionation to measure the particle size distribution (PSD) of macrobial eDNA, specifically Common Carp
(hereafter referred to as Carp) eDNA. We compared it to the PSDs of total eDNA (from all organisms) and
suspended particle matter (SPM). We quantified Carp mitochondrial eDNA using a custom qPCR assay, total
eDNAwith fluorometry and SPMwith gravimetric analysis.
3. In a lake and a pond, we found Carp eDNA in particles from>180 to<02 lm, but it was most abundant
from 1 to 10 lm. Total eDNA was most abundant below 02 lm, and SPM was most abundant above 100 lm.
SPM consisted of ≤01% total eDNA, and total eDNA consisted of ≤00004% Carp eDNA. 02 lm filtration
maximized Carp eDNA capture (85% 6%) while minimizing total (i.e. non-target) eDNA capture
(48% 3%), but filter clogging limited this pore size to a sample volume<250 mL. Tomitigate this limitation,
we estimated a continuous PSD model for Carp eDNA and derived an equation for calculating isoclines of pore
size and water volume that yield equivalent amounts of Carp eDNA.
4. Our results suggest that aqueousmacrobial eDNApredominantly exists insidemitochondria or cells, and that
settling may therefore play an important role in its fate. For optimal eDNA capture, we recommend 02 lm
filtration or a combination of larger pore size and water volume that exceeds the 02 lmisocline. In situ filtration
of large volumes could maximize detection probability when surveying large habitats for rare organisms. Our
method for eDNA particle size analysis enables future research to compare the PSDs of eDNA from other
organisms and environments, and to easily apply themfor ecological monitoring.

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Turner et al. 2014_particle_filter size.pdf “Turner et al. 2014_particle_filter size”		775.23 KB	application/pdf

Particle size distribution and optimal capture of aqueous macrobial eDNA

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