Synergistic effects of three sterol biosynthesis inhibiting fungicides on the toxicity of a pyrethroid and neonicotinoid insecticide to bumble bees

Iverson, Aaron; Hale, Casey; Richardson, Leeah; Miller, Olivia; McArt, Scott H.

doi:10.1007/s13592-019-00681-0

Cited by 33 publications

(15 citation statements)

References 37 publications

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“…It is important to note that neonicotinoids show synergistic toxicity with certain fungicides that may be used simultaneously in agricultural settings. Thiamethoxam has been shown to have synergistic toxicity with myclobutanil (Iverson et al 2019) and imazalil (Raimets et al 2018), and clothianidin has been shown to act synergistically with propiconazole (Sgolastra et al 2017). Thus, although chronic exposure to field‐realistic concentrations of acetamiprid did not alter adult survival, microcolony development, or brood production, in combination with fungicides or other pesticides, acetamiprid may negatively affect growth and survival at a lower concentration.…”

Section: Discussionmentioning

confidence: 99%

Effects of the Neonicotinoid Acetamiprid in Pollen on Bombus impatiens Microcolony Development

Camp

Batres

Williams

et al. 2020

Enviro Toxic and Chemistry

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Honey bees and other wild bee species including bumble bees have experienced population declines in recent decades. Although many stressors are implicated in bee population declines, much attention has focused on neonicotinoid pesticides, which are widely used and known to be toxic to pollinators. One neonicotinoid, acetamiprid, has been studied very little in bumble bees, despite its use on bumble bee-pollinated crops. We assessed the impacts of acetamiprid to the North American bumble bee Bombus impatiens using the microcolony model. We examined nest growth, development, and subsequent nest productivity as measured by drone production. We found that high concentrations of acetamiprid in pollen (4520 µg/kg) significantly impacted nest growth, development, and, ultimately, reproduction (drone production). We found the no-observable-adverse effect level to be 45.2 µg/kg. Overall, acetamiprid has the potential to negatively impact reproductive endpoints for B. impatiens. However, effects occurred at concentrations substantially higher than expected environmental concentrations that would be achieved when following label rates. Further work is required to assess the effects of this pesticide on B. impatiens via alternate routes of exposure and on queenright colonies.

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Section: Discussionmentioning

confidence: 99%

Effects of the Neonicotinoid Acetamiprid in Pollen on Bombus impatiens Microcolony Development

Camp

Batres

Williams

et al. 2020

Enviro Toxic and Chemistry

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“…The majority of pesticides tested for negative effects on bees have been insecticides. A smaller number of studies have measured the effects of fungicides on bee health, either alone or in combination with insecticides (Carnesecchi et al 2019;Iverson et al 2019). Certain fungicide and insecticide combinations are known to have synergistic effects, leading to increased toxicity to honey bees (Pilling et al 1995;Thompson and Wilkins 2003).…”

Section: Response To Pesticide Exposurementioning

confidence: 99%

Managed honey bees as a radar for wild bee decline?

et al. 2020

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Wild and managed bees are essential for global food security and the maintenance of biodiversity. At present, the conservation of wild bees is hampered by a huge shortfall in knowledge about the trends and status of individual species mainly due to their large diversity and variation in life histories. In contrast, the managed Western honey bee Apis mellifera is one of the best studied and monitored insects in existence. Since similar drivers may be relevant for the decline of wild bees and losses of managed honey bees, this raises the possibility that monitoring of honey bees may help to detect threatened regions for wild bees, thereby fostering urgently required conservation measures. However, this possible relationship has not yet been explicitly tested for. Moreover, research currently focused on honey bees as a model species may yield important insights into wild insect susceptibility to stressors and vice versa. Here we use the bees of Europe as a model to show that managed honey bees are not suitable surrogates for detecting declines in wild bees. A direct comparison of the response of wild bees and honey bees to the same threats (nutritional deficiencies, parasites and pathogens, pesticides, and a changing climate) shows that, whilst some of their responses may be similar at the individual level, when considered at the reproductive level (individuals versus colonies), many of their responses diverge. These results reinforce the need for basic research into wild bee biology, the need for national monitoring schemes for wild bee populations, and the call for conservation actions tailored to the individual ecologies of wild bee species.wild bees / indicator species / species specific / sociality / populations

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“…An experimental design comparing the impact of oral consumption of insecticide + fungicide mixtures on three bee species (A. mellifera, B. terrestris, and Osmia bicornis) found a small but maintained increase in clothianidin toxicity when combined with propiconazole, which was especially pronounced for the two non-Apis species with an almost three-fold increase for O. bicornis (Robinson et al, 2017). In a similar study, contact exposure of insecticides + fungicides, approximating LD 20 values and maximum sublethal levels, respectively, resulted in synergistic toxicity to B. impatiens workers (Iverson et al, 2019). Specifically, a synergistic interaction was noted for the triazole SBI fungicide difenoconazole when mixed with the pyrethroid bifenthrin, resulting in a maximum synergy ratio of 1.48.…”

Section: Non-apis Bees (Bombus and Solitary Species)mentioning

confidence: 75%

“…Since they are often applied in agricultural crop production systems throughout the year, including periods of bloom (Bosch and Blas, 1994;Andert et al, 2016;Zubrod et al, 2019;Heller et al, 2020), Apis and non-Apis bee species can come into contact with these chemicals while actively pollinating. Simulating these scenarios, laboratory, and semi-field studies have demonstrated the impacts of fungicide and herbicide exposure (as both single chemicals and in combination with other pesticides) on lethal and sublethal toxicity to different species of managed bees (Fisher et al, 2017;Heard et al, 2017;Iverson et al, 2019). Several recent studies have also linked physiological changes at the molecular and the genetic levels in bees after exposure to these agricultural chemicals (Jumarie et al, 2017;Mao et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Effects of Fungicide and Herbicide Chemical Exposure on Apis and Non-Apis Bees in Agricultural Landscape

Belsky

Joshi

2020

Front. Environ. Sci.

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Fungicide and herbicide chemistries are commonly applied in agricultural production systems and other agricultural landscapes during flowering periods, which are concurrent with the timing of bee-dependent pollination services in many plant species. As a result, bees can be exposed to these pesticides while foraging crops and other flowering plants in the landscape where they have been administered. Laboratory and semi-field studies simulating these pesticide exposure scenarios have demonstrated lethal and sub-lethal impacts to both Apis and non-Apis species of domesticated bees. Exposure to fungicides and herbicides has also been attributed to bee genetic and molecular-level changes in some cases. Herbicides can also indirectly impact bees as a result of decreasing weeds and other flowering plants that serve as nutrient resources for foraging bees. We analyze a series of recent studies concerning the toxicity of fungicides and herbicides to Apis and non-Apis bees as a basis for forming our views on key priorities regarding the direction of future research initiatives in this area. Exploring the impacts of agricultural pesticides beyond insecticides to bees is timely given the documented bee declines in the last decade and the resulting widescale interest in identifying the different drivers of these declines among the biological and the ecological scientific communities.

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Synergistic effects of three sterol biosynthesis inhibiting fungicides on the toxicity of a pyrethroid and neonicotinoid insecticide to bumble bees

Cited by 33 publications

References 37 publications

Effects of the Neonicotinoid Acetamiprid in Pollen on Bombus impatiens Microcolony Development

Effects of the Neonicotinoid Acetamiprid in Pollen on Bombus impatiens Microcolony Development

Managed honey bees as a radar for wild bee decline?

Effects of Fungicide and Herbicide Chemical Exposure on Apis and Non-Apis Bees in Agricultural Landscape

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