Abstract
Chile is the second largest global producer of farmed salmon. The growth of salmon production has not been free of environmental challenges, such as the increasing use of pesticides to control the parasitic load of the sea lice Caligus rogercresseyi. The lack of the specificity of pesticides can potentially affect non-target organisms, as well as the structure and functioning of aquatic ecosystems. The aim of this study, was to understand the effect of pesticides on natural microbial communities to the addition of the anti-lice pesticide azamethiphos, deltamethrin and emamectin benzoate, and their potential impact in ammonium uptake rates in the coast off central-southern Chile and Northern Patagonia. The addition of pesticides on natural microbial communities resulted in a rapid response in ammonium uptake, which was significant for the single use of pesticide, azamethiphos and emamectin benzoate, as well as the combination, azamethiphos, deltamethrin and emamectin benzoate. In northern Patagonia, azamethiphos addition produced a 53% decrease in photoautotrophic uptake. However, an increase, although variable, was observed in chemoautotrophic uptake. Emamectin benzoate produced a 36 to 77% decrease in chemo and photoautotrophic ammonium uptake, respectively. The combined use of pesticides, also produced up to 42% decrease in both photo and chemoautotrophic assimilation. We conclude that the use of pesticides in salmon farming produces diverse responses at the microbial level, stimulating and/or inhibiting microbial communities with subsequent impact on nitrogen budgets. Further studies are necessary to understand the impact of pesticides in the ecology of central-southern and northern Patagonia, Chile.
Highlights
Chile is the second largest global producer of farmed salmon, with an annual production of over 700 thousand tons (Avendaño-Herrera, 2018)
To understand the impact of pesticides on non-target organisms and biogeochemistry, we investigated the potential effect of three pesticides used against C. rogercresseyi on photo and chemoautotrophic ammonium uptake in two key regions of the Chilean coast that hold high levels of biological productivity but contrasting levels of influence from salmon farming
Studies oriented on the impacts of anti-lice pesticides to microbial communities involved in primary production are quite limited (Knapp et al, 2005; Burridge et al, 2010; RainFranco et al, 2018)
Summary
Chile is the second largest global producer of farmed salmon, with an annual production of over 700 thousand tons (Avendaño-Herrera, 2018). The intensive use of pesticides to control sea lice infections of Caligus rogercresseyi has become a key environmental concern for Chilean aquaculture (Millanao et al, 2011; Núñez-Acuña et al, 2015; Avendaño-Herrera, 2018). Since the earliest reported infections, sea lice in Chile have been controlled using chemicals originally used in agriculture (Reyes and Bravo, 1983). Feed additives such as emamectin benzoate have been used since the 1990s (Bravo, 2003; Bravo et al, 2008) and later complemented by pyrethroids such as deltamethrin in 2007 due to the appearance of resistance of C. rogercresseyi to emamectin benzoate. Diflubenzuron was used between 2008 and 2012 and the organophosphate azamethiphos was introduced in Chile in 2013 (Helgesen et al, 2014)
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