Abstract
AbstractWhile many studies have considered the ability of eDNA to assess animal communities in lacustrine settings, fewer have considered riverine systems, particularly those spanning the environmental gradients present in large river basins. Such dynamic systems are challenging for eDNA biomonitoring due to differing eDNA transport distances in rivers and the effects of river chemistry. To address this challenge, we focused on the Thames River system, UK, which has exceptional historical fish records providing a baseline to test the accuracy of eDNA metabarcoding in recovering fish community structure across both fresh and tidal zones. Two primer sets targeting 12S and CO1 regions were used to capture fish communities across the Thames catchment, from the upper freshwaters to the mid estuary. eDNA was collected at 35 sites, 14 of which were simultaneously paired with traditional fish surveys for direct comparison. We demonstrated that eDNA metabarcoding consistently detected more freshwater species than traditional methods, despite extensive sampling effort using the latter. In contrast, metabarcoding did not perform as well as traditional approaches in estuarine waters, although results included the novel detection of the protected sea lamprey. We further demonstrated that minor variations in the recovery of all approaches would not impact on the assessment of simple ecological models of community structure and, thus, some variability between approaches should not be viewed as a serious hindrance to uptake. Rather, our findings support a growing consensus that eDNA can reliably detect fish communities across dynamic freshwater habitats.
Highlights
Environmental (e)DNA metabarcoding has rapidly become a robust biomonitoring tool to accurately assess the diversity of animal, fish, communities in lacustrine systems, (Doble et al, 2020; Lawson Handley et al, 2019; Valdez-Moreno et al, 2019)
This study is one of the first to measure the efficiency of eDNA-based biomonitoring in a large dynamic river catchment from upper reaches through to estuary
We have shown eDNA metabarcoding in freshwater river systems detects greater species richness than traditional catch survey methods
Summary
Environmental (e)DNA metabarcoding has rapidly become a robust biomonitoring tool to accurately assess the diversity of animal, fish, communities in lacustrine systems, (Doble et al, 2020; Lawson Handley et al, 2019; Valdez-Moreno et al, 2019). The dynamic nature of riverine systems presents a suite of conditions that are thought to influence eDNA transport and persistence, and while studies have attempted to understand the abiotic factors affecting eDNA detection in lotic systems (e.g., Barnes et al, 2020; Jerde et al, 2016; Shogren et al, 2018) there remains a higher degree of uncertainty regarding inferred species detections using eDNA (Evans & Lamberti, 2018; Thalinger et al, 2020). Due to the variable abiotic conditions of riverine habitats, there are few lotic eDNA studies spanning environmental gradients of salinity (but see Sales et al (2021) and García-Machado et al (2021)). The validation of eDNA metabarcoding across such dynamic lotic environments is crucial for its acceptance as a feasible tool for monitoring riverine biodiversity
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