Consistent effects of pesticides on community structure and ecosystem function in freshwater systems

Rumschlag, Samantha L.; Mahon, Michael B.; Hoverman, Jason T.; Raffel, Thomas R.; Carrick, Hunter J.; Hudson, Peter J.; Rohr, Jason R.

doi:10.1038/s41467-020-20192-2

Cited by 74 publications

(63 citation statements)

References 40 publications

(18 reference statements)

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“…With a global annual application of pesticides exceeding 4.1 million tons (FAO 2020), their occurrence in surface and ground waters is increasingly reported (Wittmer et al 2010, Ippolito et al 2015, Stehle and Schulz 2015, in addition to the recurrent presence of other agrochemicals such as fertilizers (V€ or€ osmarty et al 2010). Despite these global trends, there are a limited number of studies addressing how the rising load and diversity of synthetic agrochemicals entering freshwaters affect the ecological functioning of communities and ecosystems (Gessner and Tlili 2016, Mazor et al 2018, Reid et al 2019; but see Rumschlag et al 2020).…”

Section: Introductionmentioning

confidence: 99%

Widespread agrochemicals differentially affect zooplankton biomass and community structure

Hébert

Fugère

Beisner

et al. 2021

Ecological Applications

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Anthropogenic environmental change is causing habitat deterioration at unprecedented rates in freshwater ecosystems. Despite increasing more rapidly than many other agents of global change, synthetic chemical pollution—including agrochemicals such as pesticides—has received relatively little attention in freshwater community and ecosystem ecology. Determining the combined effects of multiple agrochemicals on complex biological systems remains a major challenge, requiring a cross‐field integration of ecology and ecotoxicology. Using a large‐scale array of experimental ponds, we investigated the response of zooplankton community properties (biomass, composition, and diversity metrics) to the individual and joint presence of three globally widespread agrochemicals: the herbicide glyphosate, the neonicotinoid insecticide imidacloprid, and nutrient fertilizers. We tracked temporal variation in zooplankton biomass and community structure along single and combined pesticide gradients (each spanning eight levels), under low (mesotrophic) and high (eutrophic) nutrient‐enriched conditions, and quantified (1) response threshold concentrations, (2) agrochemical interactions, and (3) community resistance and recovery. We found that the biomass of major zooplankton groups differed in their sensitivity to pesticides: ≥0.3 mg/L glyphosate elicited long‐lasting declines in rotifer communities, both pesticides impaired copepods (≥3 µg/L imidacloprid and ≥5.5 mg/L glyphosate), whereas some cladocerans were highly tolerant to pesticide contamination. Strong interactive effects of pesticides were only recorded in ponds treated with the combination of the highest doses. Overall, glyphosate was the most influential driver of aggregate community properties of zooplankton, with biomass and community structure responding rapidly but recovering unequally over time. Total community biomass showed little resistance when first exposed to glyphosate, but rapidly recovered and even increased with glyphosate concentration over time; in contrast, taxon richness decreased in more contaminated ponds but failed to recover. Our results indicate that the biomass of tolerant taxa compensated for the loss of sensitive species after the first exposure, conferring greater community resistance upon a subsequent contamination event; a case of pollution‐induced community tolerance in freshwater animals. These findings suggest that zooplankton biomass may be more resilient to agrochemical pollution than community structure; yet all community properties measured in this study were affected at glyphosate concentrations below common water quality guidelines in North America.

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Section: Introductionmentioning

confidence: 99%

Widespread agrochemicals differentially affect zooplankton biomass and community structure

Hébert

Fugère

Beisner

et al. 2021

Ecological Applications

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“…While such experiments are crucial to improve ecological risk assessment of pesticides and the mechanistic understanding of their specific modes of action and detrimental effects, they often overlook the possibility that populations can evolve resistance to applied toxicants (e.g. using ‘naïve’ pooled populations and communities of zooplankton, Rumschlag et al, 2020 ). Evolved pesticide resistance in natural populations of Daphnia in response to agricultural pesticide application was shown both across spatial gradients (organophosphates: Bendis & Relyea, 2014 ; carbamates: Coors et al, 2009 ; Jansen et al, 2015 ) as well as in response to historical contamination (resurrection ecology, organophosphates: Simpson et al, 2017 ).…”

Section: Introductionmentioning

confidence: 99%

Genetic differentiation in pesticide resistance between urban and rural populations of a nontarget freshwater keystone interactor, Daphnia magna

Brans

Almeida

Fajgenblat

2021

Evolutionary Applications

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“…Furthermore, predicting the effects of pesticides could be simplified if organisms that are taxonomically related or share similar functional roles within an ecosystem have similarities in their responses to pesticides, a trend that has been shown in previous toxicological research (Hua & Relyea, 2014;Ippolito et al, 2012;van den Berg et al, 2021). For example, our previous research has shown consistency in the effects of pesticides by class and type on parasite transmission, ecosystem functions, and macroinvertebrate and amphibian communities (Rumschlag et al, 2019(Rumschlag et al, , 2020. In addition, organisms that share functional roles in a community have been shown to respond similarly to types and classes of pesticides (Rumschlag et al, 2020).…”

Section: Introductionmentioning

confidence: 98%

Pesticides alter ecosystem respiration via phytoplankton abundance and community structure: Effects on the carbon cycle?

Rumschlag

Casamatta

Mahon

et al. 2021

Global Change Biology

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Freshwater systems are critical to life on earth, yet they are threatened by the increasing rate of synthetic chemical pollution. Current predictions of the effects of synthetic chemicals on freshwater ecosystems are hampered by the sheer number of chemical contaminants entering aquatic systems, the diversity of organisms inhabiting these systems, the myriad possible direct and indirect effects resulting from these combinations, and uncertainties concerning how contaminants might alter ecosystem metabolism via changes in biodiversity. To address these knowledge gaps, we conducted a mesocosm experiment that elucidated the responses of ponds composed of phytoplankton and zooplankton to standardized concentrations of 12 pesticides, nested within four pesticide classes, and two pesticide types. We show that the effects of the pesticides on algae were consistent within herbicides and insecticides and that responses of over 70 phytoplankton species and genera were consistent within broad taxonomic groups. Insecticides generated top-down effects on phytoplankton community composition and abundance, which were associated with persistent increases in ecosystem respiration. Insecticides had direct toxic effects on cladocerans, which led to competitive release of copepods. These changes in the zooplankton community led to a decrease in green algae and a modest increase in diatoms. Herbicides did not change phytoplankton composition but reduced total phytoplankton abundance. This reduction in phytoplankton led to short-term decreases in ecosystem respiration. Given that ponds release atmospheric carbon and that worldwide pesticide pollution continues to increase exponentially, scientists and policy makers should pay more attention to the ways pesticides alter the carbon cycle in ponds via changes in communities, as demonstrated by our results. Our results show that these predictions can be simplified by grouping pesticides into types and species into functional groups.Adopting this approach provides an opportunity to improve the efficiency of risk assessment and mitigation responses to global change.

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Consistent effects of pesticides on community structure and ecosystem function in freshwater systems

Cited by 74 publications

References 40 publications

Widespread agrochemicals differentially affect zooplankton biomass and community structure

Widespread agrochemicals differentially affect zooplankton biomass and community structure

Genetic differentiation in pesticide resistance between urban and rural populations of a nontarget freshwater keystone interactor, Daphnia magna

Pesticides alter ecosystem respiration via phytoplankton abundance and community structure: Effects on the carbon cycle?

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