Abstract

Here we report the molecular networks associated with the mucosal and systemic responses to peracetic acid (PAA), a candidate oxidative chemotherapeutic in Atlantic salmon (Salmo salar). Smolts were exposed to different therapeutic doses (0, 0.6 and 2.4 mg/L) of PAA for 5 min, followed by a re-exposure to the same concentrations for 30 min 2 weeks later. PAA-exposed groups have higher external welfare score alterations, especially 2 weeks after the re-exposure. Cases of fin damage and scale loss were prevalent in the PAA-exposed groups. Transcriptomic profiling of mucosal tissues revealed that the skin had 12.5 % more differentially regulated genes (DEGs) than the gills following PAA exposure. The largest cluster of DEGs, both in the skin and gills, were involved in tissue extracellular matrix and metabolism. There were 22 DEGs common to both mucosal tissues, which were represented primarily by genes involved in the biophysical integrity of the mucosal barrier, including cadherin, collagen I α 2 chain, mucin-2 and spondin 1a. The absence of significant clustering in the plasma metabolomes amongst the three treatment groups indicates that PAA treatment did not induce any global metabolomic disturbances. Nonetheless, five metabolites with known functions during oxidative stress were remarkably affected by PAA treatments such as citrulline, histidine, tryptophan, methionine and trans-4-hydroxyproline. Collectively, these results indicate that salmon were able to mount mucosal and systemic adaptive responses to therapeutic doses of PAA and that the molecules identified are potential markers for assessing the health and welfare consequences of oxidant exposure.

Highlights

  • Chemotherapeutics are still used to treat fish diseases, stricter rules for their application have been implemented in different aquaculture-producing countries and many have shifted to more envi­ ronmentally friendly options (Buchmann, 2015; Burridge et al, 2010; Quesada et al, 2013)

  • The results of the present study provide the first comprehensive evi­ dence for the global molecular responses that were mobilised in reaction to increased reactive oxygen species (ROS) levels in the rearing environment via the application of an oxidative chemotherapeutic peracetic acid (PAA)

  • Global transcriptomic profiles of the skin and gills of PAA-exposed fish identified the former as relatively more responsive to the tested treatment doses than the latter based on the magnitude of the transcriptional changes and the number of differentially regulated genes (DEGs)

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Summary

Introduction

Chemotherapeutics are still used to treat fish diseases, stricter rules for their application have been implemented in different aquaculture-producing countries and many have shifted to more envi­ ronmentally friendly options (Buchmann, 2015; Burridge et al, 2010; Quesada et al, 2013). Peracetic acid (CH3CO3H, hereafter referred to as PAA) is a potent oxidative organic compound that has gained prominence in the last ten years as a sustainable disinfectant in aquaculture (Gesto et al, 2018; Pedersen et al, 2013). It is the peroxide of acetic acid and is commer­ cially available in an equilibrium mixture with acetic acid, H2O2 and water. The combi­ nation of PAA and H2O2 is synergistic (Alasri et al, 1992)

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