A Novel Framework for Predicting Emerging Chemical Stressor Impacts in Complex Ecosystems
Lead Research Organisation:
Imperial College London
Department Name: Life Sciences
Abstract
Freshwater ecosystems provide critical ecosystem services that underpin human societies and wellbeing: including water purification, carbon capture, and the maintenance of sustainable fisheries. However, these ecosystems are under an increasing array of threats, both in the UK and worldwide, especially from a wide range of new and emerging chemical stressors (e.g. novel antibiotics and pesticides). Freshwater biosciences and applied ecology are under-equipped for dealing with these new threats: the evidence base is lacking, there is often little or no mechanistic understanding, or predictive capacity for anticipating how these novel chemicals will operate in the real world. This is particularly true for the ecosystems of the future that are being reshaped and constructed by climate and other environmental changes.
Our project will address all these shortcomings by taken a radically different approach from the classical biomonitoring and ecotoxicology tools that have dominated for many decades. We aim to unearth the general rules by which emerging chemical stressors operate through, and alter, networks of interacting species - from microbes at the base of the food web, through to apex predators in the fish community at the top. This will involve the development of indicators of both proximate pollution, as the chemical first enters the biological system (commonly as a new food source for microbes), and also of its indirect effects as its impact propagates through the food web. For instance, we will be able to answer questions such as: if a new insecticide wipes out the invertebrates in the middle of the food web, does this trigger blooms of nuisance algae as they are no longer kept in check? To achieve this, we will develop a new suite of methods at the ecosystem level that combine lab and field experiments to detect the causal mechanisms that we currently do not understand. The experiments will be combined with mathematical modelling to predict ecosystem-level impacts. We will address both, contemporary ecosystems that could be under imminent threat from new chemical stressors, and ecosystems of the future that will emerge under different scenarios of land-use and climate change.
This will provide a completely new paradigm in chemical stressor monitoring, based on using first principles to derive a novel means of predicting "ecological surprises" that commonly arise due to the inadequacies of our current simplistic approaches when dealing with the true biocomplexity of natural systems. Our scope is for our approach to serve as a diagnostic tool for management, with research findings, for example, supporting the selection of mitigation options that deliver reduction of ecological effects. This paradigm shift will allow far more robust predictions and therefore more informed management decisions about the freshwaters of the future.
The work will bring together the field of pure and applied ecological science, to the mutual benefit of both sets of disciplines. Our proposal represents the first steps along this path to the more multidisciplinary perspective that is going to be critical for dealing with future threats to our ecosystems - from emerging chemical stressors in freshwaters to the growing list of other environmental threats looming on the horizon. Because the approach is general, it will not only pave the way for the next generation of ecological assessment in freshwaters, but it can also be adapted for applications in marine and terrestrial ecosystems.
Our project will address all these shortcomings by taken a radically different approach from the classical biomonitoring and ecotoxicology tools that have dominated for many decades. We aim to unearth the general rules by which emerging chemical stressors operate through, and alter, networks of interacting species - from microbes at the base of the food web, through to apex predators in the fish community at the top. This will involve the development of indicators of both proximate pollution, as the chemical first enters the biological system (commonly as a new food source for microbes), and also of its indirect effects as its impact propagates through the food web. For instance, we will be able to answer questions such as: if a new insecticide wipes out the invertebrates in the middle of the food web, does this trigger blooms of nuisance algae as they are no longer kept in check? To achieve this, we will develop a new suite of methods at the ecosystem level that combine lab and field experiments to detect the causal mechanisms that we currently do not understand. The experiments will be combined with mathematical modelling to predict ecosystem-level impacts. We will address both, contemporary ecosystems that could be under imminent threat from new chemical stressors, and ecosystems of the future that will emerge under different scenarios of land-use and climate change.
This will provide a completely new paradigm in chemical stressor monitoring, based on using first principles to derive a novel means of predicting "ecological surprises" that commonly arise due to the inadequacies of our current simplistic approaches when dealing with the true biocomplexity of natural systems. Our scope is for our approach to serve as a diagnostic tool for management, with research findings, for example, supporting the selection of mitigation options that deliver reduction of ecological effects. This paradigm shift will allow far more robust predictions and therefore more informed management decisions about the freshwaters of the future.
The work will bring together the field of pure and applied ecological science, to the mutual benefit of both sets of disciplines. Our proposal represents the first steps along this path to the more multidisciplinary perspective that is going to be critical for dealing with future threats to our ecosystems - from emerging chemical stressors in freshwaters to the growing list of other environmental threats looming on the horizon. Because the approach is general, it will not only pave the way for the next generation of ecological assessment in freshwaters, but it can also be adapted for applications in marine and terrestrial ecosystems.
Planned Impact
Our new predictive framework, which blends data with mathematical models, provides a novel tool for assessing the ecosystem impacts of emerging chemical stressors. This will generate a new approach that can be adapted for use in any ecosystem, and which links to current and future policy demands - including the Water Framework Directive (and its potential post-Brexit replacement) in the immediate future and other more strategic goals, such as those set out in the 25-year Lawton Report to Defra.
The main national beneficiaries of this research among the end-user and stakeholder communities include the major UK environmental, conservation and regulatory agencies (Department of Environment Food & Rural Affairs (DEFRA), Environment Agency (EA), Natural England (NE), Centre for Ecology & Hydrology (CEH), Centre for Environment, Fisheries and Aquaculture Science (CEFAS)), for whom understanding, predicting and mitigating the impacts of stressors in natural ecosystems is an essential remit. We have already engaged in discussion with all these bodies and others (listed in Project Partners) both within the UK and overseas, and they have all expressed strong support for developing the new gene-to-ecosystem approach that we are advocating.
Our approach will arm regulatory bodies with a more realistic assessment of future scenarios, based on solid ecological principles and firm empirical and mechanistic evidence. Moreover, this new research will enable commercial companies to assess the potential range of impacts that could arise in natural systems, which is impossible using the reductionist and/or phenomenological approaches that currently prevail. A range of industrial partners, including several water companies, multinational chemical firms, and environmental consultancies have established strong links with members of our consortium, so we have a clear route to transfer our outputs to the wider world.
As part of our outreach and non-academic activities beyond the academic sphere, we will set up an Stakeholder Group (derived from our industry and policy partners) which will steer us on maximising the project's outreach and influence on policy formulation. We will also use Imperial's Centre for Environmental Policy and the stakeholder networks we have developed over recent aligned projects (e.g., via NERC Biodiversity and Ecosystem Service Sustainability, Macronutrients, Environmental Microbiology and Human Health programmes; Woodward et al Large Grant).
Beyond these focal science-policy areas, our project will resonate with wider concerns about the health and ecological risks associated with emerging chemical and climate change: these are manifested across a wide range of scales, from local Citizen Science groups (such as Action for the River Kennet) to those that are more regional (e.g. the Wildlife Trusts), national (e.g. the Riverfly Partnership), international (e.g. the Freshwater Biological Association and Society for Freshwater Sciences) or global (e.g. the Intergovernmental Platform for Biodiversity and Ecosystem Services) in their reach and remit. All these bodies and many individual private citizens are concerned with conserving sustainable ecosystems, and these are conversations we have regularly at outreach events - such as the annual Imperial Festival, which has a footfall of 10,000s of visitors each year - and with various non-academic partners who are interested in our work. We have a strong track record of engagement that we have fostered over many years (e.g the OPAL initiative at Imperial and numerous policy briefings led by the Grantham Institute and the Centre for Environmental Policy).
Finally, because our approach is flexible and transferable, it offers huge potential to complement and add value to other grants being considered within this call, and if funded, we would engage with the other projects to maximise potential synergies and areas of complementarity.
(see also Pathways to Impact)
The main national beneficiaries of this research among the end-user and stakeholder communities include the major UK environmental, conservation and regulatory agencies (Department of Environment Food & Rural Affairs (DEFRA), Environment Agency (EA), Natural England (NE), Centre for Ecology & Hydrology (CEH), Centre for Environment, Fisheries and Aquaculture Science (CEFAS)), for whom understanding, predicting and mitigating the impacts of stressors in natural ecosystems is an essential remit. We have already engaged in discussion with all these bodies and others (listed in Project Partners) both within the UK and overseas, and they have all expressed strong support for developing the new gene-to-ecosystem approach that we are advocating.
Our approach will arm regulatory bodies with a more realistic assessment of future scenarios, based on solid ecological principles and firm empirical and mechanistic evidence. Moreover, this new research will enable commercial companies to assess the potential range of impacts that could arise in natural systems, which is impossible using the reductionist and/or phenomenological approaches that currently prevail. A range of industrial partners, including several water companies, multinational chemical firms, and environmental consultancies have established strong links with members of our consortium, so we have a clear route to transfer our outputs to the wider world.
As part of our outreach and non-academic activities beyond the academic sphere, we will set up an Stakeholder Group (derived from our industry and policy partners) which will steer us on maximising the project's outreach and influence on policy formulation. We will also use Imperial's Centre for Environmental Policy and the stakeholder networks we have developed over recent aligned projects (e.g., via NERC Biodiversity and Ecosystem Service Sustainability, Macronutrients, Environmental Microbiology and Human Health programmes; Woodward et al Large Grant).
Beyond these focal science-policy areas, our project will resonate with wider concerns about the health and ecological risks associated with emerging chemical and climate change: these are manifested across a wide range of scales, from local Citizen Science groups (such as Action for the River Kennet) to those that are more regional (e.g. the Wildlife Trusts), national (e.g. the Riverfly Partnership), international (e.g. the Freshwater Biological Association and Society for Freshwater Sciences) or global (e.g. the Intergovernmental Platform for Biodiversity and Ecosystem Services) in their reach and remit. All these bodies and many individual private citizens are concerned with conserving sustainable ecosystems, and these are conversations we have regularly at outreach events - such as the annual Imperial Festival, which has a footfall of 10,000s of visitors each year - and with various non-academic partners who are interested in our work. We have a strong track record of engagement that we have fostered over many years (e.g the OPAL initiative at Imperial and numerous policy briefings led by the Grantham Institute and the Centre for Environmental Policy).
Finally, because our approach is flexible and transferable, it offers huge potential to complement and add value to other grants being considered within this call, and if funded, we would engage with the other projects to maximise potential synergies and areas of complementarity.
(see also Pathways to Impact)
Organisations
Publications
Dobson B
(2022)
Predicting catchment suitability for biodiversity at national scales.
in Water research
Brasier M
(2020)
Overcoming the Obstacles Faced by Early Career Researchers in Marine Science: Lessons From the Marine Ecosystem Assessment for the Southern Ocean
in Frontiers in Marine Science
Morris OF
(2022)
Local stressors mask the effects of warming in freshwater ecosystems.
in Ecology letters
Makiola A
(2020)
Key Questions for Next-Generation Biomonitoring
in Frontiers in Environmental Science
Smith TP
(2024)
High-throughput characterization of bacterial responses to complex mixtures of chemical pollutants.
in Nature microbiology
Smith T
(2024)
High-throughput characterization of bacterial responses to complex mixtures of chemical pollutants
in Nature Microbiology
Smith T
(2024)
High-throughput characterization of bacterial responses to complex mixtures of chemical pollutants
in Nature Microbiology
Perkins R
(2024)
Down-the-drain pathways for fipronil and imidacloprid applied as spot-on parasiticides to dogs: Estimating aquatic pollution.
in The Science of the total environment
Henley S
(2020)
Changing Biogeochemistry of the Southern Ocean and Its Ecosystem Implications
in Frontiers in Marine Science
Description | We have found significant interactions between chemicals and with warming - such that current policy and projections cannot forecast the impacts of chemical pollutants in a warming world - this is a major finding as classic ecotoxicology and bio monitoring ignore these potential synergies. We have also detected widespread evidence of "hidden" chemical pollution in the form of domestic variants of pesticides banned for agricultural use in UK waters - especially in urban areas. This is another major gap in policy and science we are addressing further. |
Exploitation Route | We are currently following up ourselves as the priority. Ultimately this could feed into both regulation and future research programmes as these are major hurdles to developing a predictive approach fro the UK that we have uncovered. |
Sectors | Agriculture Food and Drink Chemicals Environment Pharmaceuticals and Medical Biotechnology |
Title | Bacterial isolate chemical responses data |
Description | Dataset of growth responses of bacterial isolates to mixtures of chemical stressors. Data present:tidy-data.csv - raw growth curves, OD600 readings recorded at hourly time intervals.spline_fits.csv - results of fitting spline curves to the growth curve data and calculating the area under the curve (AUC) as an overall metric of growth for each bacteria-stressor combination.bootstrapped-emergent-interactions.csv - results of significance testing for emergent interactions using bootstrapping methodology.bootstrapped-net-interactions.csv - results of significance testing for net interactions using bootstrapping methodology.RAxML_result.constrained_output - phylogeny of bacterial isolates in newick format with branch lengths. |
Type Of Material | Database/Collection of data |
Year Produced | 2024 |
Provided To Others? | Yes |
URL | https://figshare.com/articles/dataset/Bacterial_isolate_chemical_responses_data/25054913 |
Title | Data for: Latent functional diversity may accelerate microbial community responses to temperature fluctuations |
Description | How complex microbial communities respond to climatic fluctuations remains an open question. Due to their relatively short generation times and high functional diversity, microbial populations harbor great potential to respond as a community through a combination of strain-level phenotypic plasticity, adaptation, and species sorting. However, the relative importance of these mechanisms remains unclear. We conducted a laboratory experiment to investigate the degree to which bacterial communities can respond to changes in environmental temperature through a combination of phenotypic plasticity and species sorting alone. We grew replicate soil communities from a single location at six temperatures between 4°C and 50°C. We found that phylogenetically- and functionally-distinct communities emerge at each of these temperatures, with K-strategist taxa favoured under cooler conditions, and r-strategist taxa under warmer conditions. We show that this dynamic emergence of distinct communities across a wide range of temperatures (in essence, community-level adaptation), is driven by the resuscitation of latent functional diversity: the parent community harbors multiple strains pre-adapted to different temperatures that are able to "switch on" at their preferred temperature without immigration or adaptation. Our findings suggest that microbial community function in nature is likely to respond rapidly to climatic temperature fluctuations through shifts in species composition by resuscitation of latent functional diversity. |
Type Of Material | Database/Collection of data |
Year Produced | 2022 |
Provided To Others? | Yes |
URL | http://datadryad.org/stash/dataset/doi:10.5061/dryad.f1vhhmh0g |
Description | ERCITE Science Meeting |
Form Of Engagement Activity | Participation in an activity, workshop or similar |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Other audiences |
Results and Impact | Annual ERCITE Science Meeting to report across all three projects led by CEH and Imperial |
Year(s) Of Engagement Activity | 2023 |
Description | Policy Briefing |
Form Of Engagement Activity | A press release, press conference or response to a media enquiry/interview |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Policymakers/politicians |
Results and Impact | Grantham Institute Policy briefing note - released 20th March 2023m with associated press briefings |
Year(s) Of Engagement Activity | 2023 |
Description | Policy briefing paper on multiple stressors |
Form Of Engagement Activity | A magazine, newsletter or online publication |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Policymakers/politicians |
Results and Impact | We produced a briefing paper outlining the need for dealing with multiple stressors in aquatic systems, targeting lay and policy audiences and held a panel discussion event at Imperial on the same topic |
Year(s) Of Engagement Activity | 2018 |
URL | https://www.imperial.ac.uk/grantham/publications/multiple-stressors-in-freshwater-ecosystems-biocide... |
Description | Stakeholder engagement meeting |
Form Of Engagement Activity | Participation in an activity, workshop or similar |
Part Of Official Scheme? | No |
Geographic Reach | National |
Primary Audience | Industry/Business |
Results and Impact | The workshop was a scoping exercise to determine how best to engage with stakeholders and other end-users via the ERCITE Programme and to identify target audiences for these next steps |
Year(s) Of Engagement Activity | 2019 |