Abstract
Salmonid Rickettsial Septicaemia (SRS), caused by Piscirickettsia salmonis, is the most important infectious disease in the Chilean salmon farming industry. An opportunity to control this disease is to use functional micronutrients to modulate host mechanisms of response to the infection. Since P. salmonis may affect the host antioxidant system in salmonids, particularly that dependent on selenium (Se), we hypothesized that fish’s dietary selenium supplementation could improve the response to the bacterial infection. To address this, we defined a non-antibiotic, non-cytotoxic concentration of selenium to evaluate its effect on the response to in vitro infections of SHK-1 cells with P. salmonis. The results indicated that selenium supplementation reduced the cytopathic effect, intracellular bacterial load, and cellular mortality of SHK-1 by increasing the abundance and activity of host glutathione peroxidase. We then prepared diets supplemented with selenium up to 1, 5, and 10 mg/kg to feed juvenile trout for 8 weeks. At the end of this feeding period, we obtained their blood plasma and evaluated its ability to protect SHK-1 cells from infection with P. salmonis in ex vivo assays. These results recapitulated the observed ability of selenium to protect against infection with P. salmonis by increasing the concentration of selenium and the antioxidant capacity in fish’s plasma. To the best of our knowledge, this is the first report of the protective capacity of selenium against P. salmonis infection in salmonids, becoming a potential effective host-directed dietary therapy for SRS and other infectious diseases in animals at a non-antibiotic concentration.
Highlights
Aquaculture is the third-largest productive sector in Chile, where the main species produced and exported are salmonids like Atlantic salmon (Salmo salar), Pacific salmon (Oncorhynchus kisutch), and Rainbow trout (Oncorhynchus mykiss)
Infected SHK-1 cells non treated with SSP significantly reduced their viability in comparison with non-infected SHK-1 cells (52.21% of reduction), while infected SHK-1 cells treated with SSP1 or SSP5 improved cell viability compared to infected non treated SHK-1 cells (27.85% and 57.85% of improvement, respectively) (p-value < 0.05, Figure 5D). These results indicate that selenium, at a non-antibiotic and non-cytotoxic concentration, reduces the cytopathic effect, the infection progression, and the mortality of SHK-1 cells infected with P. salmonis
Previous investigations on the transcriptomic response of salmonids to P. salmonis infection support identifying critical biological processes and pathways that are good candidates to be manipulated by this strategy [8, 9, 33], highlighting the antioxidant host metabolism
Summary
Aquaculture is the third-largest productive sector in Chile, where the main species produced and exported are salmonids like Atlantic salmon (Salmo salar), Pacific salmon (Oncorhynchus kisutch), and Rainbow trout (Oncorhynchus mykiss). It has been described that more than 80% of the total antibiotics used in the Chilean salmon industry are against SRS since the doses tend to be higher than those administered to other bacterial diseases given the intracellular facultative nature of P. salmonis [4]. This strategy and the emergence of bacterial strains resistant to these antibiotics have severely impacted the country’s image, and the sustainability of the industry has been strongly questioned because of this [5].
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