Biofilms Provide New Insight into Pesticide Occurrence in Streams and Links to Aquatic Ecological Communities

Mahler, Barbara J.; Schmidt, Travis S.; Nowell, Lisa H.; Qi, Sharon L.; Metre, Peter C. Van; Hladik, Michelle L.; Carlisle, Daren M.; Munn, Mark D.; May, Jason T.

doi:10.1021/acs.est.9b07430

Cited by 40 publications

(23 citation statements)

References 80 publications

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“…GAMs relate a univariate response variable (i.e., total mayfly abundance) with parametric predictors (i.e., measured of pesticide exposure and covariates) that depend on nonparametric smoother functions. First, we related total mayfly abundance to 10 natural covariates used in California Stream Condition Index to account for naturally occurring variation in aquatic assemblages and to minimize confounding (spurious associations between natural and anthropogenic factors) with anthropogenic stressors, in this case, pesticides ( 81 , 82 ). The covariates represent measures of site location (latitude, longitude, site elevation, and elevation range of watershed), basin size, long-term air temperature, precipitation (long-term and summer average), bulk soil density, and soil erodibility ( 81 ).…”

Section: Methodsmentioning

confidence: 99%

Ecological consequences of neonicotinoid mixtures in streams

et al. 2022

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Neonicotinoid mixtures are common in streams worldwide, but corresponding ecological responses are poorly understood. We combined experimental and observational studies to narrow this knowledge gap. The mesocosm experiment determined that concentrations of the neonicotinoids imidacloprid and clothianidin (range of exposures, 0 to 11.9 μg/liter) above the hazard concentration for 5% of species (0.017 and 0.010 μg/liter, respectively) caused a loss in taxa abundance and richness, disrupted adult emergence, and altered trophodynamics, while mixtures of the two neonicotinoids caused dose-dependent synergistic effects. In 85 Coastal California streams, neonicotinoids were commonly detected [59% of samples ( n = 340), 72% of streams], frequently occurred as mixtures (56% of streams), and potential toxicity was dominated by imidacloprid (maximum = 1.92 μg/liter) and clothianidin (maximum = 2.51 μg/liter). Ecological responses in the field were consistent with the synergistic effects observed in the mesocosm experiment, indicating that neonicotinoid mixtures pose greater than expected risks to stream health.

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Section: Methodsmentioning

confidence: 99%

Ecological consequences of neonicotinoid mixtures in streams

et al. 2022

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“…The source receptor modeling and mass fraction analysis are widely being used to identify potential PAH sources in streambed sediment samples [194]. Biofilms and aquatic organisms have been employed as bio-indicators to detect and assess the impacts associated with streambed pollution [195,196]. The general impact assessment methodology includes finding the sources and occurrence of the pollutants, verification/quantification of the pollutant concentration in the streambed using analytical methods in the laboratory and comparing with standard values (as given in any guidelines) followed by statistical analysis and development of impact indices [39].…”

Section: Impact Assessment Methodologies: Pros and Consmentioning

confidence: 99%

Streambed pollution: A comprehensive review of its sources, eco-hydro-geo-chemical impacts, assessment, and mitigation strategies

Mohanavelu¹,

Shrivastava²,

Naganna³

2021

Preprint

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Streambeds are among the important components of stream ecosystems and support several critical ecosystem services such as transformation of organic matter and nutrients and provide habitat for aquatic organisms. Increasing anthropogenic influence introduces multiple stressors to the stream networks resulting in pollution of streambeds, which in turn, could have detrimental effects on overall stream ecosystem health. However, there are gaps in the current understanding of the impacts of streambed pollution and the mitigation strategies lack holistic approach. In this review, we first present a global inventory to highlight the status of streambed pollution around the globe. Next, we synthesize the state-of-art knowledge of conventional and emerging forms of contaminants, their overall impacts on stream ecosystem functions, and finally present future directions to comprehend the problem of streambed pollution. We highlight that fine sediments and plastics (found especially in urban streambeds) are among the major physical pollutants of streambed pollution and the chemical pollutants generally comprise of hydrophobic compounds including various legacy contaminants such as polychlorinated biphenyl (PCB), dichlorodiphenyltrichloroethane (DDT), a wide range of pesticides and a variety of heavy metals. Further, in recent years, highly polar and hydrophilic emerging contaminants such as micro-plastics, pharmaceutical waste and personal care products have been identified in rivers around the world. We stress that the impacts of streambed pollution have been largely studied with discipline-driven perspectives amongst which the ecological impacts have received a lot of attention in the past. To present a comprehensive outlook, this review also synthesizes the hydrological, geomorphological and biochemical impacts of different forms of streambed pollutants. In the end, we endorse the positive and negative aspects of the current impact assessment methodologies and also highlight various physical, chemical and biological remediation measures that could be applied to alleviate streambed pollution.

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“…This ‘ecological memory’ made biofilms reliable indicators to assess and monitor the health of aquatic ecosystems, with the development of many structurally based or functionally based methods (Burns & Ryder, 2001; Sabater et al., 2007; Wu, 2017h). In a recent survey monitoring pesticide occurrence in 54 Californian small streams, biofilms were shown to contain, in average, four times as many current‐use pesticides like pyrethroids as in streambed sediments (Mahler et al., 2020). As biofilms adsorb toxicants and form the basis of aquatic food webs, they make toxicants bioavailable to consumers, thus posing a risk to their health (see part 4.3).…”

Section: Importance Of Biofilms Growing On Non‐biological Interfacesmentioning

confidence: 99%

“…As biofilms adsorb toxicants and form the basis of aquatic food webs, they make toxicants bioavailable to consumers, thus posing a risk to their health (see part 4.3). In conclusion, not only are biofilms the sentinels of aquatic ecosystems, they are also a critical control point to monitor and understand the fate of toxicants in food webs (Bonnineau et al., 2020; Mahler et al., 2020).…”

Section: Importance Of Biofilms Growing On Non‐biological Interfacesmentioning

confidence: 99%

The significance of biofilms to human, animal, plant and ecosystem health

et al. 2021

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Biofilms are matrix‐enclosed communities that represent the most dominant and active mode of microbial life on Earth. Because biofilms are inherently more productive than any equivalent planktonic community, they are of great relevance to all environments they inhabit. However, their existence and importance are still poorly known by the general public, conservation practitioners and environmental policymakers. Most micro‐organisms of multicellular organisms (including humans, animals and plants) occur in the form of true biofilms or biofilm‐like structures that play vital roles in their development, physiology and immunity. Conversely, some biofilms can have a negative effect on host health. Biofilms growing on non‐biological surfaces are essential components of many terrestrial and marine ecosystems: they form the basis of food webs and ensure nutrient cycling and bioremediation in natural systems. However, environmental biofilms can promote the persistence of human pathogens, produce harmful toxins, foul and corrode surfaces in natural and man‐made settings; all of which can have significant health and economic implications. There is a knowledge gap about the roles of biofilms in the epidemiology of wildlife emerging infectious diseases, yet these pose a major threat to public health, biodiversity and sustainability. The drivers of global environmental change all affect biofilm structure and functions. The consequences for host and ecosystem health are, however, poorly understood. While the concept of a healthy microbiome (as opposed to dysbiosis) is emerging in medicine and conservation biology, the concept of a healthy biofilm remains to be defined in environmental sciences. Here, we use an integrative approach to (a) review current knowledge on the roles of biofilms growing on biological and non‐biological interfaces for the health of multicellular organisms and ecosystems, and (b) provide future research directions to address identified knowledge gaps. Giving the biofilm life‐form its full importance will help understand the effects of global environmental change on these communities and, in turn, on human, animal, plant and ecosystem health.

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Biofilms Provide New Insight into Pesticide Occurrence in Streams and Links to Aquatic Ecological Communities

Cited by 40 publications

References 80 publications

Ecological consequences of neonicotinoid mixtures in streams

Ecological consequences of neonicotinoid mixtures in streams

Streambed pollution: A comprehensive review of its sources, eco-hydro-geo-chemical impacts, assessment, and mitigation strategies

The significance of biofilms to human, animal, plant and ecosystem health

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