Detection differences between eDNA and mid-water trawls are driven by fish biomass and habitat preferences

Q1 Agricultural and Biological Sciences
Environmental DNA Pub Date : 2024-07-14 DOI:10.1002/edn3.586
Tessa Rehill, Ben Millard-Martin, Matt Lemay, Kate Sheridan, Anya Mueller, Evan Morien, Rute B. G. Clemente-Carvalho, Brian P. V. Hunt, Jennifer M. Sunday
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Abstract

Marine scientific trawl surveys are commonly used to assess the distribution and population size of fisheries-related species, yet the method is effort-intensive and can be environmentally destructive. Sequencing environmental DNA (eDNA) from water samples can reveal the presence of organisms in a community without capturing them; however, we expect the detectability of taxa to differ between eDNA and trawl surveys, and understanding how species traits and population variables contribute to detection differences can help calibrate our expectations from each form of sampling. Here, we coupled eDNA metabarcoding and capture trawl surveys in British Columbia, Canada, to examine species traits that explain recurrent differences in detectability between the two methods, including habitat, body size, and biomass. At the regional scale, 17 of 23 fish species (74%) captured by the trawl were detected by eDNA metabarcoding, and 39 additional species were detected by eDNA sampling only. We found that eDNA metabarcoding disproportionately detected trawl-caught species with greater local biomass (i.e., greater biomass in the adjacent trawl). Fish detected only in eDNA had a greater range of body lengths and a broader range of habitat preferences outside the trawls' target size and sampling areas. Our results suggest that with our level of sampling, eDNA metabarcoding can adequately recapitulate detection of fish communities detected by trawl surveys, but with a bias toward fish of high population biomass and greater inclusion of fish from outside the trawled area.

Abstract Image

鱼类生物量和生境偏好决定了 eDNA 和中层拖网之间的检测差异
海洋科学拖网调查通常用于评估渔业相关物种的分布和种群数量,但这种方法耗费大量人力物力,而且可能对环境造成破坏。从水样中测序环境 DNA(eDNA)可以在不捕获生物的情况下揭示群落中生物的存在;然而,我们预计 eDNA 和拖网调查对分类群的可探测性会有所不同,了解物种特征和种群变量是如何导致探测差异的,有助于校准我们对每种取样形式的预期。在此,我们将加拿大不列颠哥伦比亚省的 eDNA 代谢标码和捕获拖网调查结合起来,研究可解释两种方法之间可探测性经常性差异的物种特征,包括栖息地、体型和生物量。在区域范围内,拖网捕获的 23 种鱼类中有 17 种(74%)通过 eDNA 代谢编码法检测到,另有 39 种仅通过 eDNA 采样法检测到。我们发现,通过 eDNA 代谢标定法检测到的拖网捕获鱼种中,当地生物量较大(即邻近拖网的生物量较大)的鱼种比例过高。仅通过 eDNA 检测到的鱼类在拖网的目标尺寸和取样区域之外有更大的体长范围和更广泛的栖息地偏好。我们的研究结果表明,根据我们的取样水平,eDNA 代谢标码可以充分再现拖网调查所发现的鱼类群落,但会偏向于高种群生物量的鱼类,并更多地包含拖网区域外的鱼类。
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来源期刊
Environmental DNA
Environmental DNA Agricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics
CiteScore
11.00
自引率
0.00%
发文量
99
审稿时长
16 weeks
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