Abstract
The high tolerance of Litopenaeus vannamei to a wide range of salinity (1–50 psu) makes this species an excellent candidate for culture under low salinity, decreasing shrimp epidemics and water pollution in some coastal areas. However, salinity levels outside the optimal range could impose several physiological constraints that would in turn affect growth and survival, particularly in the presence of additional stressors (e.g. high densities, handling practices, and hypoxia). Despite shrimp susceptibility to individual stressors has been widely addressed, information regarding response to chronic and acute stressors combined and its relation to diet is scarce. Thus, the aim of our study was to determine the effect of diet on the susceptibility to chronic (low salinity) and acute (hypoxia and escape response) stressors in terms of culture performance and physiological indicators. We evaluated overall performance during culture of L. vannamei at low salinity (6 psu), fed with an experimental diet with low protein and high carbohydrate content (26% protein and 6% fish meal plus probiotic mixture) and compared to a commercial formula with high protein and low carbohydrate content (40% crude protein and 20% fish meal without probiotic mixture). At the end of the rearing experiment, shrimp were exposed to two types of acute stress, hypoxia and escape. Biochemical (hemocyanin, total proteins, glucose, and lactate) and bioenergetic (adenylic energy charge and arginine phosphate levels) variables were measured to assess chronic stress response (salinity) and acute stress response (hypoxia or escape). The experimental diet resulted in higher muscle energy status that was not affected by low salinity, although lipid levels were lower under this condition. This diet partially counteracted the low performance at low salinity and promoted greater protein efficiency. Hypoxia induced strong hyperglycemic and lactate increase as response, whereas escape response was characterized by a depletion of arginine phosphate levels, with a stronger decrease in shrimp fed experimental diet, due to the high initial level of this reserve. Some data (glucose levels in hemolymph and lipids in hepatopancreas) suggest that shrimp under chronic stress conditions (low salinity and high densities) present a low ability to respond to subsequent acute stressors such as hypoxia or escape. This work indicates that diet can increase the energy status of shrimp, enabling them to overcome potential multifactorial stressors, which are common in farming systems.
Highlights
Shrimp culture has been one of the major growth areas in worldwide aquaculture during the last 55 years, a production of 4.156 million tons was reached in 2016 (FAO, 2018)
The lowest Protein efficiency ratio (PER) (F1,12 = 6.4, P = 0.026) and highest Feed conversion ratio (FCR) (F1,12 = 6.2, P = 0.029) were detected in shrimp fed control diet and reared at 6 psu, these presented the lowest productive performance when compared with the rest of the treatments (Table 4)
Hemocyanin was affected by salinity; such effect was dependent on diet: differences between both salinities were observed only for the experimental diet (6 psu: 51.5 ± 3.8 mg.mL−1 and 37 psu: 69.1 ± 4.1 mg.mL−1, P < 0.01)
Summary
Shrimp culture has been one of the major growth areas in worldwide aquaculture during the last 55 years, a production of 4.156 million tons was reached in 2016 (FAO, 2018). Salinity levels outside the optimal range and prolonged exposure could impose several physiological constraints that would in turn affect growth and survival This is the case for culture under low salinities, where hyper-osmoregulation implies high energy demand, and nutritional requirements of shrimp grown at low salinities has been extensively studied (for reviews see Romano & Zeng, 2012; Li et al, 2017). A sparing effect of protein could be suggested when intermediate levels of carbohydrates are included in shrimp diet at low salinity (Wang et al, 2014; Wang et al, 2015). Essential lipids such as phospholipids and cholesterol, as well as supplementation of minerals resulted in better performance of shrimp at low salinity (Gong et al, 2004). Supplementation of Lactobacillus plantarum improved resistance to low salinity stress test (Zheng et al, 2017)
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