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Environmental Measurements Methods
Does size matter? An experimental evaluation of the relative abundance and decay rates of aquatic eDNA. Jonas Bylemans, Elise M Furlan, Dianne M Gleeson, Christopher M Hardy, and Richard P Duncan Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b01071 • Publication Date (Web): 14 May 2018 Downloaded from http://pubs.acs.org on May 14, 2018
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Does size matter? An experimental evaluation of the
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relative abundance and decay rates of aquatic eDNA.
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Jonas Bylemans,*, †, ‡ Elise M. Furlan,†, ‡ Dianne M. Gleeson,†, ‡ Christopher M. Hardy,§, ‡
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Richard P. Duncan†
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†
Institute for Applied Ecology, University of Canberra, Canberra, ACT 2617, Australia
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‡
Invasive Animals CRC, University of Canberra, Canberra, ACT 2617, Australia
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§
CSIRO Land and Water, GPO Box 1700, Canberra, ACT 2601, Australia
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KEYWORDS
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Environmental DNA, fish, eDNA target length, quantitative real-time PCR
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ABSTRACT
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Environmental DNA (eDNA) is increasingly used to monitor aquatic macro-fauna. Typically,
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short mitochondrial DNA fragments are targeted because these should be relatively more abundant
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in the environment as longer fragments will break into smaller fragments over time. However,
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longer fragments may permit more flexible primer design and increase taxonomic resolution for
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eDNA metabarcoding analyses, and recent studies have shown that long mitochondrial eDNA
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fragments can be extracted from environmental water samples. Nuclear eDNA fragments have
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also been proposed as targets but little is known about their persistence in the aquatic environment.
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Here we measure the abundance of mitochondrial eDNA fragments of different length, and short
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nuclear eDNA fragments, originating from captive fish in experimental tanks, and test whether
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longer mitochondrial and short nuclear fragments decay faster than short mitochondrial fragments
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following fish removal. We show that, when fish are present, shorter mitochondrial fragments are
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more abundant in water samples than both longer mitochondrial fragments and the short nuclear
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eDNA fragment. However, the rate of decay following fish removal was similar for all fragment
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types, suggesting that the differences in abundance resulted from differences in the rates at which
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different fragment types were produced rather than differences in their decay rates.
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ABSTRACT ART
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INTRODUCTION
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Environmental DNA (eDNA) extracted from environmental samples can be used to monitor the
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presence/absence of particular species and obtain biodiversity estimates.1–3 A key issue with using
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eDNA for monitoring purposes is that DNA in the environment can decay rapidly. Over time,
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longer DNA fragments break into smaller fragments causing the latter to be relatively more
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common in environmental samples.4–8 Mitochondrial DNA fragments are also likely to be more
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abundant in environmental samples than nuclear DNA fragments because mitochondrial DNA is
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present in higher copy numbers per cell and is believed to be less susceptible to environmental
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decay. Several studies have shown that recovery rates from environmental samples are lower for
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long relative to short fragments, and for nuclear relative to mitochondrial DNA fragments.4,6,9–11
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Consequently, most studies have used short mitochondrial DNA barcodes (i.e. typically between
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50 and 200 base pairs (bp)), particularly for ancient and highly degraded samples (e.g. ice cores,
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permafrost, fossil bones, faeces, etc.).4,9,12–16
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Environmental DNA from water samples is increasingly being used as a monitoring tool.17–19
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While the optimization of sampling, capturing and extraction protocols has received considerable
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attention, the relative abundance and decay of DNA fragments of different size and origin (i.e.
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mitochondrial versus nuclear) has not been formally evaluated.20–23 Within the water column, the
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relative abundance of different DNA fragments depends on both their rate of production and the
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rate at which fragments are removed from the water column (i.e. through decay, settling, advection
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and dispersion).24 While the source of eDNA is often unclear (e.g. from faeces, urine, mucous,
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etc.), the abundance of eDNA in the environment is known to be correlated with species’ biomass,
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ontogeny and metabolism, which are likely associated with differences in production rates.24–29 On
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the other hand, the decay of eDNA is known to be influenced by temperature, pH, UV-radiation
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and microbial activity.27,30–33 While DNA fragments can decay rapidly in some sample types, such
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as sediment and faecal samples,4,8,34 recent evidence suggests that the aquatic matrix preserves
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eDNA relatively well. For example, DNA fragments believed to be more susceptible to decay (i.e.
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long mitochondrial fragments and nuclear fragments) have been successfully extracted and
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amplified from water samples.35–38 One reason for these findings may be the fact that aquatic
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eDNA occurs mainly within whole organelles and/or cells, meaning it may be partly protected
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from environmental factors that could promote decay.39,40 However, a thorough evaluation of the
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relative abundance and decay rates of different eDNA fragments is needed as the ability to use
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non-standard fragments (i.e. longer mitochondrial fragments and nuclear fragments) could
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advance eDNA-based monitoring of aquatic biodiversity through more flexible primer design and
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increased taxonomic resolution of barcodes for whole community analyses (i.e. eDNA
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metabarcoding).
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Here we use replicate tanks stocked with three different densities of common goldfish (Carassius
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auratus) to quantify the relative abundance and decay rates of mitochondrial eDNA fragments of
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different size and a short nuclear eDNA fragment. We use these results to evaluate whether the
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differences in the relative abundances of the different fragments are caused by their susceptibility
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to environmental decay. Furthermore, using the eDNA degradation data and two different
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modelling approaches we aimed to gain a deeper understanding of the eDNA decay process in
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freshwater environments. Finally, we highlight the potential implications of our findings for
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advancing eDNA-based monitoring.
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MATERIALS AND METHODS
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Primer design and testing
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We designed primers to amplify different sized fragments (ca. 100, 300 and 500 bp) of the
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mitochondrial cytochrome c oxidase subunit I (COI) gene and a short (ca. 100 bp) fragment of the
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nuclear internal transcribed spacer (ITS) region of common goldfish. Target regions were selected
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based on high genetic variability between species and the presence of multiple copies within a
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cell.6,41,42 Fragment sizes for the mitochondrial DNA were chosen based on current size
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recommendations for eDNA studies (i.e. length of 50 to 200 bp) and the conditions currently
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preferred for High-Throughput Sequencing (HTS) platforms (i.e. 550 to 570 bp using 2 x 300 bp
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paired-end sequencing on the Illumina MiSeq allowing for a 50 to 30 bp overlap for sequence
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merging).3,43 The primer pairs were designed and tested both in silico and in vitro (Supporting
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Information). All primer pairs used for further analyses are given in Table 1. Hereafter, different
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DNA fragments will be referred to by the eDNA fragment ID’s in Table 1 which consist of the
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target region (COI or ITS) followed by the total length of the amplicon in brackets (i.e. COI
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(096bp), COI (285bp) and COI (515bp) for the short, medium and long mitochondrial fragments
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respectively and ITS (095bp) for the short nuclear fragment).
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Experimental protocol
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We sterilised all experimental and sampling equipment before use using a 10% bleach solution
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followed by thorough rinsing with UV-sterilized tap water. All tanks were set-up with a gravel
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substrate and a ca. 10 cm piece of PVC pipe for habitat enrichment. A constant airflow was
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provided to each tank through a cylindrical air stone (15 x 25 mm) and tanks were kept a constant
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temperature of 20 °C and a 12 h daylight cycle for the duration of the experiment. Goldfish (mean
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mass = 5.7 g, range = 3.3-9.5 g) purchased from a local pet shop were stocked individually in 10
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L, 30 L and 60 L tanks filled with UV-sterilized tap water to simulate high density (HD), medium
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density (MD) and low density (LD) conditions, respectively in three replicate treatments (n = 9
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tanks). A negative control tank (NCT), consisting of a 60 L tank without fish, was included to test
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for cross-contamination. Fish were fed half a cube of frozen artemia (ca. 1.4 g) every second day
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and no food was added to the NCT. Prior to stocking the tanks with fish, a 50 mL water sample
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was collected from each tank to test that they were initially free from goldfish DNA, with the time
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of this sample set to zero hours (0 h). Additional 50 mL water samples were collected at 2, 6, 24,
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72, 168 and 336 h after stocking. Immediately after collecting the 336 h sample, all fish were
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removed from the tanks and additional water samples were collected at 338, 342, 360, 408, 504,
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672 and 1008 h. Water volumes within tanks were kept constant by adding 50 mL of UV-sterilized
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tap water after each sample collection. Fin clips were collected from each fish after they were
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removed from the tanks. Genomic DNA was extracted from the fin clips and the COI and ITS
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target regions were amplified using PCR. Amplicons were sequenced for all (COI) or two (ITS)
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of the experimental animals to test for the presence of individual primer-template mismatches
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(Supporting Information).
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Sample processing and qPCR analyses
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Processing and analyses of eDNA samples were performed in a trace DNA laboratory at the
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University of Canberra (Australia). This laboratory is spatially separated from other laboratories
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and is UV-radiated nightly to reduce the risk of contamination. Spatially separated room were used
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for eDNA extractions and PCR set-up with the latter having a positive air pressure.
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From each 50 ml water sample, eDNA was captured by filtering onto a glass fibre filter with a
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nominal pore size of 1.2 µm (MicroScience, Taren Point, Australia). While this approach may
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inherently bias the results due to a reduced likelihood of capturing free floating DNA, a 1.2 µm
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pore size is more suitable for field applications and would thus better reflect the accessible eDNA
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during field surveys. Negative equipment controls (NEC) were obtained for each sample by
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filtering 500 mL of UV-sterilized water through the sterilized equipment prior to filtering samples.
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Environmental DNA was extracted using the PowerWater DNA Extraction Kit (MoBio
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Laboratories, Carlsbad, USA) following manufacturing instructions (i.e. 100 µL of eDNA eluent).
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For each timepoint, one NEC was extracted to test for cross-contamination occurring during either
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the filtrations or DNA extraction phase. DNA extracts were transferred to 2 mL screw-cap tubes
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and stored at -20 °C for downstream analyses.
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Quantitative real-time PCR (qPCR) was used to determine eDNA concentrations. The absence
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of goldfish DNA from all negative control samples (i.e. water samples collected from the
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experimental tanks prior to introducing goldfish, water samples from the NCT and NEC’s) was
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confirmed by performing six qPCR replicates for the short COI and ITS fragments. For all
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experimental samples, six qPCR replicates were performed with each primer set. Due to the large
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number of qPCR analyses and the costs of probe-based qPCR assays, a SYBR® Green chemistry
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with previously published reaction conditions scaled down to a final reaction volume of 15 µL
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containing 1.5 µL of DNA extract was used.37 All qPCR reactions were set-up in a dedicated room
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within the trace DNA laboratory in 384-well plates using the epMotion® 5075 Liquid Handling
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Workstation (Eppendorf, Hamburg, Germany). Six non-template controls (NTC) and a standard
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curve, consisting of six qPCR replicates for each concentration (i.e. 3 x 101 to 3 x 106 molecules
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per reaction), were included on each plate. Synthetic gBlock® fragments (IDT, Coralville, USA)
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were used to construct standard curves. Synthetic fragments contained bp mismatches with the
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sequences of the experimental animals (Supporting Information) and Sangers sequencing of qPCR
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amplicons obtained from eDNA samples was used to evaluate potential cross-contamination (i.e.
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amplicon sequences should only match the sequences from the experimental animals).
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All qPCR analyses were performed using the Viia7 Real-Time PCR System (Applied
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Biosystems, Foster City, USA) under previously published cycling conditions.37 Amplification
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and melt curves were visually inspected and replicates were excluded from further analyses if the
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amplification curve did not show a clear exponential phase and/or the melt curve deviated from
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those obtained with genomic goldfish DNA (Supporting Information). Finally, for each fragment
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a subset of the PCR amplicons (ca. 10% of all samples showing a positive amplification) were
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purified using the MinElute PCR Purification Kit (Qiagen, Hilden, Germany) and Sanger
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sequenced at the ARCF Biomolecular Resource Facility (Australian National University) using an
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Applied Biosystems 3730xl DNA Analyzer (Thermo Fisher Scientific) following the
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manufacturer’s protocol.
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Data analyses
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Environmental DNA concentrations ([eDNA]) were expressed as copy numbers per mL of tank
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water and qPCR replicates that failed to amplify were assumed to have a concentration of zero
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copies per mL. Concentrations were calculated using eDNA copies per qPCR reaction (eDNA),
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the volume of template DNA used per qPCR reaction (1.5 x 10-3 mL) and the sample volume (50
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mL). A correction for the dilution effect, caused by adding UV-sterilized water to the experimental
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tanks, was included using the sample volume (50 mL) and the volume of the experimental tank
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expressed in mL (VT) (Equation 1). Nonetheless, eDNA measurements obtained after removing
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fish from the experimental tanks will be influenced by both eDNA decay and the dilution effect.
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As only small sample volumes were used, the dilution effect is unlikely to influence the overall
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eDNA decay trends observed.
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[𝑒𝐷𝑁𝐴] =
(𝑒𝐷𝑁𝐴 × (100 × 10−3 𝑚𝐿)) ((1.5 × 10−3 𝑚𝐿) × 50 𝑚𝐿)
×
(𝑉𝑇 −50 𝑚𝐿) 𝑉𝑇
(1)
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For further statistical analyses, eDNA concentrations were transformed using the natural logarithm
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(i.e. loge([eDNA] + 1)) and all analyses were conducted using R version 3.4.1 with the packages
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tidyverse and nlme.44–46 The data obtained for two experimental tanks was excluded from the final
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analyses as bp mismatches were observed between the primers and the template sequences for two
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experimental animals (see the “RESULTS AND DISCUSSION” section for a more detailed
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description).
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Inspection of the data prior to fish removal revealed that all eDNA fragments reached
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equilibrium concentrations after approximately 24 h (Supporting Information). We therefore
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estimated equilibrium eDNA concentrations using the data from 24 h until fish were removed (i.e.
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sampling time ≥ 24 h and sampling time ≤ 336 h). We fitted a linear mixed-effect model to the
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data with loge-transformed eDNA concentrations as the response variable. Fish density and
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fragment type were included as categorical fixed effects, and nested random effects were included
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to correct for pseudo-replication (i.e. individual samples nested within individual tanks). We
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estimated differences in eDNA equilibrium concentrations between density treatments and
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fragment types relative to a reference class set to zero (COI (096bp) in the HD treatment).
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The decay of aquatic eDNA has previously been modelled assuming a first-order exponential
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decay function.1,36,47 The concentration of a particular eDNA fragment at time (t), C(t), can thus
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be modelled using Equation 2 with C0 representing the equilibrium eDNA concentration prior to
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fish removal and k being the decay constant.
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𝐶(𝑡) = 𝐶0 × 𝑒 −𝑘𝑡
(2)
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While this first-order decay model may be a simplification of the true decay process, it allows us
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to quantify the decay constants for each fragment by density treatment combination, k, and to
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compare how decay constants vary under different conditions.31,40 Decay constants were estimated
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using the data obtained at least 6 hours after fish removal (i.e. sampling time ≥ 342 h). This was
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done to avoid a spike in eDNA concentrations immediately after fish removal in one tank, possibly
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caused by increased stress levels in the experimental animal and/or the resuspension of faecal
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matter. We also excluded sampling times for which all qPCR replicates failed to amplify, which
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implied that eDNA abundance had decayed below the detection limits (i.e. here assumed to be zero
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copies per mL). We estimated the parameters of the exponential decay model by fitting linear
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models using loge-transformed eDNA concentrations as the response variable. A linear mixed-
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effect model was used to evaluate the impact of fish density and fragment type on the decay
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constant. Sampling time was included as a continuous fixed effect along with categorical fixed
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effects for fish density and fragment type. Two-way interactions between sampling time and fish
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density, and sampling time and fragment type were also included (significant interactions imply
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differing slopes and hence differing values of the decay constant, k, for density and fragment type).
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A nested random effect was included to correct for pseudo-replication (i.e. individual samples
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nested within individual tanks). Differences in decay constants between density treatments and
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fragment types were estimated relative to a reference class set to zero (COI (096bp) in the HD
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treatment). To evaluate the fit of the exponential decay model we used separate linear models for
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each fragment by density treatment combination and calculated the Akaike Information Criterion
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(AIC).
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The assumption that the eDNA decay process can be summarized into a single decay constant
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may not apply if some fragments were more prone to decay than others (e.g. fragments present
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within cells versus free floating DNA). This would result in the decay constant decreasing over
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time as fragments prone to rapid decay (i.e. having a higher decay constant) were removed first
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from the population, leaving behind fragments with lower decay constants. To test if the eDNA
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decay constant varied over time for each treatment by fragment combination, we fitted a Weibull
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decay model to the data (Equation 3). The Weibull parameter (β) in this model allows for the decay
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constant to vary with time, with values of β less than one indicating a decreasing decay constant
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and values larger than one indicating an increasing decay constant over time. When β equals one
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the model reduces to the first-order exponential decay function.
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𝐶(𝑡) = 𝐶0 × 𝑒 (−𝑘 × 𝑡
𝛽)
(3)
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We estimated parameters for the Weibull model for each fragment by density treatment
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combination as above (i.e. using the data obtained at least 6 hours after fish removal and sampling
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times for which all replicates tested negative for eDNA excluded). We used the AIC to evaluate
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the fit of the model for each treatment by fragment combination and compared AIC values from
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the Weibull model with those obtained from the first-order exponential decay model to assess
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which model best described the data.
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RESULTS AND DISCUSSION
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Primer design and testing
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All primer pairs successfully passed the in silico and in vitro evaluation. The performance of the
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different primer pairs was evaluated based on the standard curves included in the qPCR analyses.
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The results show that the amplification efficiency decreases with increasing amplicon length and
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that the efficiency of the primers targeting the ITS (096bp) fragment is lower compared to those
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for the COI (095bp) fragment (Table 1). Nonetheless, this will not affect the validity of the eDNA
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quantifications as both standard curve samples and experimental samples will be amplified with a
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comparable efficiency.48
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The COI barcode sequences (660bp in length) from the experimental animals revealed that two
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mitochondrial haplotypes were present. Two out of the nine sequences had a 98% match with C.
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auratus voucher specimens, which were used as a basis for primer development. This genetic
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variation in the mitochondrial genome resulted in a reduced or failed amplification in two of the
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experimental tanks when using the goldfish specific COI primers. The data obtained from these
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replicate tanks was thus excluded from further analysis (i.e. removal of one LD and one HD
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replicate tank). In contrast, identical sequences were obtained for the ITS regions of two
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experimental animals with different COI haplotypes and these were used as a basis for primer
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development (Supporting Information). Primers targeting the ITS (096bp) fragment showed
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consistent amplification in all replicate tanks. While this suggests that the ITS region can be a
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valuable target for the development of primers specific to species with a high mitochondrial
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genetic variability (e.g. goldfish), the relative abundance and the decay rate of the ITS (096bp)
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fragment also needs to be considered.
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Effect of fragment size
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Equilibrium concentrations of mitochondrial eDNA fragments decreased with decreasing fish
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density, which is consistent with previously published results.28,29 The model estimates of the mean
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eDNA concentrations in the MD and LD treatments were on average 0.43 and 0.16 times that of
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the HD treatment, respectively (Figure 1). The 95% confidence intervals around the model
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estimates revealed a significant decrease in equilibrium concentrations for longer mitochondrial
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fragments, which is consistent with the prevailing view that shorter mitochondrial DNA fragments
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are more abundant in environmental samples (Figure 1).4–6 The mean estimates for the equilibrium
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concentrations of the COI (285bp) and COI (515bp) fragments were 0.76 and 0.31 times that of
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the COI (096bp) fragment, respectively. In contrast, a previous study by Deagle et al.4 revealed
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that a 327 bp sea lion DNA fragment is on average 0.099 (± 0.057) less abundant than a 91 bp
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fragment in sea lion faecal samples. Furthermore, a study by Dell’Anno et al.34 found that
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degradation rates for extracellular DNA in marine sediments were 7-100 times higher than those
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observed in the water column, and Deiner et al.38 recently showed that even complete
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mitochondrial genomes can be extracted and amplified from aquatic eDNA samples.
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Consequently, the aquatic matrix seems to preserve longer DNA fragment relatively well.
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Environmental DNA decay constants estimated from the first-order exponential decay models
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ranged from 0.11 to 0.77 day-1, which are towards the lower end of previously published records
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(i.e. 0.05 to 17.9 day-1).19,26,27,30,31 This could be a consequence of the UV-sterilized tap water used
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in the experimental tanks, which is likely to reduce the influence of microbial organisms on the
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decay process. However, similar decay constants have been obtained by Thomsen et al.19 (i.e. 0.32
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and 0.70 day-1) when using natural seawater and by Strickler et al.31 (i.e. 0.05-0.34 day-1) when
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using tap water inoculated with micro-organisms. More importantly, we expected to find higher
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decay constants for longer fragments if DNA fragmentation (i.e. events such as strand breaks that
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prevent DNA replication during PCR) is a random process and a major cause of eDNA decay.4,9
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However, given the strongly overlapping confidence intervals around the estimates of the decay
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constants we can conclude that there is no clear evidence that larger eDNA fragments have higher
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decay constants (Figure 2). In contrast to our findings, a recent study did report a significantly
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higher decay constant for a 719 bp fragment relative to a 127 bp fragment.36 The smaller
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differences in length between fragments in our study may partly explain why we did not observe
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an effect. Alternatively, the short decay time used by Jo et al.36 (i.e. up to 48 hours after fish
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removal) may have resulted in an over-estimation of decay constant given that we found that decay
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rates can be high initially but decrease over time (see “Comparison of eDNA decay models”
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section). Nevertheless, the absence of a clear length dependent decay constant in our study
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provides evidence that DNA fragmentation may not be the rate determining step in the decay
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process of aquatic eDNA. In the current study, the rate of decay may be more strongly affected by
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the time taken to break down phospholipid bilayers as aquatic eDNA is mainly present in
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mitochondria or whole cells and the methods used here will primarily capture this eDNA
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fraction.39,40
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Equilibrium concentrations of aquatic eDNA are a function of both eDNA production and decay
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rates. As decay rates did not vary consistently by fragment length, our results imply that the
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differences in equilibrium concentrations were caused primarily by differences in the production
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rates of eDNA fragments of different length. Intestinal cells present in faecal matter are an
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important source of aquatic eDNA.25,49 Given that DNA in faeces is often fragmented, some
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proportion of the eDNA released by animals may already be fragmented.4 Therefore, the eDNA
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released into the water column through fish excrements might explain why production rates differ
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for fragments of different length. This inherent fragmentation of eDNA released by aquatic
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organisms will need to be considered in future studies aimed at evaluating the relative contribution
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of DNA fragmentation on the overall decay process.
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Effect of fragment origin
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A comparison of the relative abundance of nuclear and mitochondrial eDNA fragments of similar
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size reveals that nuclear eDNA appears less abundant than the mitochondrial fragment. The
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estimates of the equilibrium eDNA concentrations showed that the ITS (095bp) fragment was 0.29
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times less abundant than the COI (096bp) fragment (Figure 1). While some previous studies have
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shown that nuclear eDNA may be equally or even more abundant than mitochondrial fragments,
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species-specific differences in the number of ribosomal operons are well known.37,41,49,50
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Counter to our expectations, the first-order decay constant estimated from the nuclear data was
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lower for the ITS (095bp) fragment than the COI (096bp) fragment (Figure 2). When considering
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the absolute estimates for the decay constant for each fragment by treatment combination, we only
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find a significant difference between the ITS (095bp) and COI (096bp) decay constants in the HD
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treatment (Supporting Information). Within the HD treatment, the build-up of fish excrements is
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likely to influence both the pH and microbial activity, which in turn can increase the decay
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constant.30,31 While we did observe increased decay constants for the mitochondrial fragments in
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the HD treatments, no significant increase was observed for the ITS (095bp) fragment
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(Supplementary Information). Consequently, the impact of environmental conditions on the decay
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process may differ depending on the origin of the DNA fragment.
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Comparison of eDNA decay models
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Modelling of aquatic eDNA has commonly assumed an exponential rate of decay.19,30,31 However
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we found that a Weibull decay model with a decay constant that decreases over time better
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describes the eDNA decay process. The mean estimate of log(β) was less than zero (implying β
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