100 years of anthropogenic impact causes changes in freshwater functional biodiversity

Niamh Eastwood; Jiarui Zhou; Romain Derelle; Mohamed Abou-Elwafa Abdallah; William A Stubbings; Yunlu Jia; Sarah E Crawford; Thomas A Davidson; John K Colbourne; Simon Creer; Holly Bik; Henner Hollert; Luisa Orsini; Detlef Weigel

doi:10.7554/eLife.86576.1

100 years of anthropogenic impact causes changes in freshwater functional biodiversity

Niamh Eastwood^*, Jiarui Zhou, Romain Derelle, Mohamed Abou-Elwafa Abdallah, William A Stubbings, Yunlu Jia, Sarah E Crawford, Thomas A Davidson, John K Colbourne, Simon Creer, Holly Bik, Henner Hollert, Luisa Orsini, Detlef Weigel

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

Despite efforts from scientists and regulators, biodiversity is declining at an alarming rate. Unless we find transformative solutions to preserve biodiversity, future generations may not be able to enjoy nature’s services. We have developed a conceptual framework that establishes the links between biodiversity dynamics and abiotic change through time and space using artificial intelligence. Here, we apply this framework to a freshwater ecosystem with a known history of human impact and study 100 years of community-level biodiversity, climate change and chemical pollution trends. We apply explainable network models with multimodal learning to community-level functional biodiversity measured with multilocus metabarcoding, to establish correlations with biocides and climate change records. We observed that the freshwater community assemblage and functionality changed over time without returning to its original state, even if the lake partially recovered in recent times. Insecticides and fungicides, combined with extreme temperature events and precipitation, explained up to 90% of the functional biodiversity changes. The community-level biodiversity approach used here reliably explained freshwater ecosystem shifts. These shifts were not observed when using traditional quality indices (e.g. Trophic Diatom Index). Our study advocates the use of high-throughput systemic approaches on long-term trends over species-focused ecological surveys to identify the environmental factors that cause loss of biodiversity and disrupt ecosystem functions.

Original language	English
Article number	RP86576
Number of pages	28
Journal	eLife
Volume	12
DOIs	https://doi.org/10.7554/eLife.86576.1 https://doi.org/10.7554/elife.86576
Publication status	Published - 7 Nov 2023

Bibliographical note

Acknowledgements:
We thank Kerry Walsh and Glenn Watts, the UK Environment Agency, for helpful discussions on the application of the approach presented here within regulatory frameworks. The metabarcoding data were generated by EnviSion, BioSeqencing and BioComputing at the University of Birmingham (https://www.envision-service.com/). The DDT chemical data were generated by the GEES Mass Spectrometry Facility at the University of Birmingham. Sediment sampling and dating was completed by Goldsmith Ecology, Somerset. We thank Stephen Kissane for technical assistance in generating high throughput sequencing data, Dr Xiaojing Li for helpful discussions on functional analysis and Chantal Jackson for the artwork of Figure 1. This work was funded by the Alan Turing Institute (under EPSRC grant R-BIR-001); and the NERC highlights grant LOFRESH (NE/N005716/1). NE is supported by the Biotechnology and Biological Sciences Research Council (Midlands Integrative Biosciences Training Partnership (MIBTP; BB/M01116X/1)). LO and HH have been supported by the RobustNature Cluster of Excellence Initiative (internal prefunding of Goethe University Frankfurt).

Keywords

functional biodiversity
None
multilocus metabarcoding
machine learning
freshwater
sedaDNA

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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EastwoodN2023100yeaFinal published version, 5.17 MBLicence: Creative Commons: Attribution (CC BY)

Understanding the ecological relevance of eDNA in freshwater lotic ecosystems
Orsini, L. & Colbourne, J.
Natural Environment Research Council
1/12/15 → 31/10/21
Project: Research Councils

Cite this

Eastwood, N., Zhou, J., Derelle, R., Abdallah, M. A.-E., Stubbings, W. A., Jia, Y., Crawford, S. E., Davidson, T. A., Colbourne, J. K., Creer, S., Bik, H., Hollert, H., Orsini, L., & Weigel, D. (2023). 100 years of anthropogenic impact causes changes in freshwater functional biodiversity. eLife, 12, Article RP86576. https://doi.org/10.7554/eLife.86576.1, https://doi.org/10.7554/elife.86576

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title = "100 years of anthropogenic impact causes changes in freshwater functional biodiversity",

abstract = "Despite efforts from scientists and regulators, biodiversity is declining at an alarming rate. Unless we find transformative solutions to preserve biodiversity, future generations may not be able to enjoy nature{\textquoteright}s services. We have developed a conceptual framework that establishes the links between biodiversity dynamics and abiotic change through time and space using artificial intelligence. Here, we apply this framework to a freshwater ecosystem with a known history of human impact and study 100 years of community-level biodiversity, climate change and chemical pollution trends. We apply explainable network models with multimodal learning to community-level functional biodiversity measured with multilocus metabarcoding, to establish correlations with biocides and climate change records. We observed that the freshwater community assemblage and functionality changed over time without returning to its original state, even if the lake partially recovered in recent times. Insecticides and fungicides, combined with extreme temperature events and precipitation, explained up to 90% of the functional biodiversity changes. The community-level biodiversity approach used here reliably explained freshwater ecosystem shifts. These shifts were not observed when using traditional quality indices (e.g. Trophic Diatom Index). Our study advocates the use of high-throughput systemic approaches on long-term trends over species-focused ecological surveys to identify the environmental factors that cause loss of biodiversity and disrupt ecosystem functions.",

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author = "Niamh Eastwood and Jiarui Zhou and Romain Derelle and Abdallah, {Mohamed Abou-Elwafa} and Stubbings, {William A} and Yunlu Jia and Crawford, {Sarah E} and Davidson, {Thomas A} and Colbourne, {John K} and Simon Creer and Holly Bik and Henner Hollert and Luisa Orsini and Detlef Weigel",

note = "Acknowledgements: We thank Kerry Walsh and Glenn Watts, the UK Environment Agency, for helpful discussions on the application of the approach presented here within regulatory frameworks. The metabarcoding data were generated by EnviSion, BioSeqencing and BioComputing at the University of Birmingham (https://www.envision-service.com/). The DDT chemical data were generated by the GEES Mass Spectrometry Facility at the University of Birmingham. Sediment sampling and dating was completed by Goldsmith Ecology, Somerset. We thank Stephen Kissane for technical assistance in generating high throughput sequencing data, Dr Xiaojing Li for helpful discussions on functional analysis and Chantal Jackson for the artwork of Figure 1. This work was funded by the Alan Turing Institute (under EPSRC grant R-BIR-001); and the NERC highlights grant LOFRESH (NE/N005716/1). NE is supported by the Biotechnology and Biological Sciences Research Council (Midlands Integrative Biosciences Training Partnership (MIBTP; BB/M01116X/1)). LO and HH have been supported by the RobustNature Cluster of Excellence Initiative (internal prefunding of Goethe University Frankfurt).",

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AU - Eastwood, Niamh

AU - Zhou, Jiarui

AU - Derelle, Romain

AU - Abdallah, Mohamed Abou-Elwafa

AU - Stubbings, William A

AU - Jia, Yunlu

AU - Crawford, Sarah E

AU - Davidson, Thomas A

AU - Colbourne, John K

AU - Creer, Simon

AU - Bik, Holly

AU - Hollert, Henner

AU - Orsini, Luisa

AU - Weigel, Detlef

N1 - Acknowledgements: We thank Kerry Walsh and Glenn Watts, the UK Environment Agency, for helpful discussions on the application of the approach presented here within regulatory frameworks. The metabarcoding data were generated by EnviSion, BioSeqencing and BioComputing at the University of Birmingham (https://www.envision-service.com/). The DDT chemical data were generated by the GEES Mass Spectrometry Facility at the University of Birmingham. Sediment sampling and dating was completed by Goldsmith Ecology, Somerset. We thank Stephen Kissane for technical assistance in generating high throughput sequencing data, Dr Xiaojing Li for helpful discussions on functional analysis and Chantal Jackson for the artwork of Figure 1. This work was funded by the Alan Turing Institute (under EPSRC grant R-BIR-001); and the NERC highlights grant LOFRESH (NE/N005716/1). NE is supported by the Biotechnology and Biological Sciences Research Council (Midlands Integrative Biosciences Training Partnership (MIBTP; BB/M01116X/1)). LO and HH have been supported by the RobustNature Cluster of Excellence Initiative (internal prefunding of Goethe University Frankfurt).

PY - 2023/11/7

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N2 - Despite efforts from scientists and regulators, biodiversity is declining at an alarming rate. Unless we find transformative solutions to preserve biodiversity, future generations may not be able to enjoy nature’s services. We have developed a conceptual framework that establishes the links between biodiversity dynamics and abiotic change through time and space using artificial intelligence. Here, we apply this framework to a freshwater ecosystem with a known history of human impact and study 100 years of community-level biodiversity, climate change and chemical pollution trends. We apply explainable network models with multimodal learning to community-level functional biodiversity measured with multilocus metabarcoding, to establish correlations with biocides and climate change records. We observed that the freshwater community assemblage and functionality changed over time without returning to its original state, even if the lake partially recovered in recent times. Insecticides and fungicides, combined with extreme temperature events and precipitation, explained up to 90% of the functional biodiversity changes. The community-level biodiversity approach used here reliably explained freshwater ecosystem shifts. These shifts were not observed when using traditional quality indices (e.g. Trophic Diatom Index). Our study advocates the use of high-throughput systemic approaches on long-term trends over species-focused ecological surveys to identify the environmental factors that cause loss of biodiversity and disrupt ecosystem functions.

AB - Despite efforts from scientists and regulators, biodiversity is declining at an alarming rate. Unless we find transformative solutions to preserve biodiversity, future generations may not be able to enjoy nature’s services. We have developed a conceptual framework that establishes the links between biodiversity dynamics and abiotic change through time and space using artificial intelligence. Here, we apply this framework to a freshwater ecosystem with a known history of human impact and study 100 years of community-level biodiversity, climate change and chemical pollution trends. We apply explainable network models with multimodal learning to community-level functional biodiversity measured with multilocus metabarcoding, to establish correlations with biocides and climate change records. We observed that the freshwater community assemblage and functionality changed over time without returning to its original state, even if the lake partially recovered in recent times. Insecticides and fungicides, combined with extreme temperature events and precipitation, explained up to 90% of the functional biodiversity changes. The community-level biodiversity approach used here reliably explained freshwater ecosystem shifts. These shifts were not observed when using traditional quality indices (e.g. Trophic Diatom Index). Our study advocates the use of high-throughput systemic approaches on long-term trends over species-focused ecological surveys to identify the environmental factors that cause loss of biodiversity and disrupt ecosystem functions.

KW - functional biodiversity

KW - None

KW - multilocus metabarcoding

KW - machine learning

KW - freshwater

KW - sedaDNA

U2 - 10.7554/eLife.86576.1

DO - 10.7554/eLife.86576.1

M3 - Article

C2 - 37933221

SN - 2050-084X

VL - 12

JO - eLife

JF - eLife

M1 - RP86576

ER -

100 years of anthropogenic impact causes changes in freshwater functional biodiversity

Abstract

Bibliographical note

Keywords

UN SDGs

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Projects

Understanding the ecological relevance of eDNA in freshwater lotic ecosystems

Cite this