Importance of eDNA taphonomy and sediment provenance for robust ecological inference: Insights from interfacial geochemistry

Q1 Agricultural and Biological Sciences
Environmental DNA Pub Date : 2024-03-11 DOI:10.1002/edn3.519
K. K. Sand, S. Jelavić, K. H. Kjær, A. Prohaska
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引用次数: 0

Abstract

Retrieval of modern and ancient environmental DNA (eDNA) from sediments has revolutionized our ability to study past and present ecosystems. Little emphasis has been placed, however, on the fundamentals of the DNA–sediment associations in environmental settings. Consequently, our understanding of mineralogic controls and geochemical processes that take place on the DNA–sediment interface, and its implications for eDNA taphonomy and provenance, remain extremely limited. Here, we apply interfacial geochemical principles to elucidate how depositional processes and the stability of DNA–sediment associations in different environments can influence our interpretation and identify possible interpretational biases arising from neglecting mineral and geochemical controls on eDNA taphonomy. We use atomic force microscopy to show how interfacial geochemical interactions drive DNA adsorption behavior and we outline how to increase the scope and resolution of ecological interpretations from eDNA by combining mineralogic composition information with experimental adsorption data. We bring the concepts together and propose how to integrate sediment provenance as well as mineralogic and geochemical principles in eDNA taphonomy analysis for improved reconstruction of past ecosystems and monitoring of modern ecosystems from eDNA data. We provide a conceptual understanding of how eDNA taphonomy and sediment provenance can be addressed and further applied to enhance the scope, resolution, and accuracy of modern and past ecological reconstructions based on eDNA data.

Abstract Image

eDNA 岩石学和沉积物产地对可靠生态推断的重要性:界面地球化学的启示
从沉积物中提取现代和古代环境 DNA(eDNA)彻底改变了我们研究过去和现在生态系统的能力。然而,我们却很少关注环境中 DNA 与沉积物关联的基本原理。因此,我们对发生在 DNA-沉积物界面上的矿物学控制和地球化学过程及其对 eDNA 移生学和来源的影响的了解仍然非常有限。在这里,我们运用界面地球化学原理来阐明沉积过程和不同环境中 DNA 与沉积物关联的稳定性如何影响我们的解释,并找出因忽视矿物和地球化学对 eDNA 移生学的控制而可能产生的解释偏差。我们利用原子力显微镜展示了界面地球化学相互作用如何驱动 DNA 吸附行为,并概述了如何通过将矿物成分信息与实验吸附数据相结合来扩大 eDNA 生态解释的范围和分辨率。我们将这些概念结合在一起,并提出如何在 eDNA 岩石学分析中整合沉积物来源以及矿物学和地球化学原理,以改进对过去生态系统的重建,并通过 eDNA 数据监测现代生态系统。我们从概念上理解了如何处理和进一步应用 eDNA 岩石学和沉积物来源,以提高基于 eDNA 数据的现代和过去生态重建的范围、分辨率和准确性。
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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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