Sodium salt medium-chain fatty acids and<i>Bacillus</i>-based probiotic strategies to improve growth and intestinal health of gilthead sea bream (<i>Sparus aurata</i>)

Simó‐Mirabet, Paula; Piazzon, M. Carla; Calduch-Giner, Josep Àlvar; Ortiz, Álvaro; Puyalto, Mónica; Sitjà‐Bobadilla, Ariadna; Pérez‐Sánchez, Jaume

doi:10.7717/peerj.4001

Cited by 42 publications

(47 citation statements)

References 72 publications

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“…This diversity is now starting to be elucidated, and microarray gene expression profiling of European sea bass intestine revealed pronounced spatial transcriptional changes with an over-representation of nutrient transporters and mucosal chemosensors of intestinal motility and secretion in anterior-medium intestine segments, whereas immunity markers are highly over-expressed in the posterior intestine segment (Calduch-Giner et al, 2016 ). This expression pattern has also been inferred for gilthead sea bream in both this and previous studies (Pérez-Sánchez et al, 2015 ; Estensoro et al, 2016 ; Simó-Mirabet et al, 2017b ) using intestinal PCR-arrays of selected markers of intestinal architecture and function. Moreover, the expression pattern of the fast-growing strain appears to be better suited to cope with enhanced feed intake and growth rates, as inferred by the up-regulated expression in the anterior intestine segment of genes involved in cell adhesion and epithelial integrity ( cdh1 and cdh17 ), mucus production ( muc2 ), Goblet cell differentiation ( hes1-b ) and FA transport ( fabp2 ).…”

Section: Discussionsupporting

confidence: 85%

“…The same relationship held true for markers of the GH/IGF axis, and we found that plasma level of IGF-I closely reflected differences in growth potentiality between fish strains, as previously observed when comparing the growth performance of gilthead sea bream with that of the stress sensitive common dentex (Bermejo-Nogales et al, 2007 ). Experimental evidence regarding the gilthead sea bream also indicates that IGF-I is highly responsive to changes in growth performance due to biotic and abiotic factors, including season and developmental stage (Mingarro et al, 2002 ; Saera-Vila et al, 2007 ), ration size (Pérez-Sánchez et al, 1995 ), crowding and handling stress (Rotllant et al, 2001 ), physical activity (Vélez et al, 2016 ), hypoxia (Martos-Sitcha et al, 2017 ) and dietary protein and lipid source (Gómez-Requeni et al, 2004 ; Benedito-Palos et al, 2007 ; Ballester-Lozano et al, 2015 ; Simó-Mirabet et al, 2017b ). Most of these changes in circulating levels of IGF-I are inversely correlated with plasma levels of GH due to the IGF-I feedback inhibition of pituitary GH synthesis and secretion (Pérez-Sánchez, 2000 ).…”

Section: Discussionmentioning

confidence: 99%

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Co-expression Analysis of Sirtuins and Related Metabolic Biomarkers in Juveniles of Gilthead Sea Bream (Sparus aurata) With Differences in Growth Performance

et al. 2018

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Sirtuins (SIRTs) represent a conserved protein family of deacetylases that act as master regulators of metabolism, but little is known about their roles in fish and livestock animals in general. The present study aimed to assess the value of SIRTs for the metabolic phenotyping of fish by assessing their co-expression with a wide-representation of markers of energy and lipid metabolism and intestinal function and health in two genetically different gilthead sea bream strains with differences in growth performance. Fish from the fast-growing strain exhibited higher feed intake, feed efficiency and plasma IGF-I levels, along with higher hepatosomatic index and lower mesenteric fat (lean phenotype). These observations suggest differences in tissue energy partitioning with an increased flux of fatty acids from adipose tissue toward the liver. The resulting increased risk of hepatic steatosis may be counteracted in the liver by reduced lipogenesis and enhanced triglyceride catabolism, in combination with a higher and more efficient oxidative metabolism in white skeletal muscle. These effects were supported by co-regulated changes in the expression profile of SIRTs (liver, sirt1; skeletal muscle, sirt2; adipose tissue, sirt5-6) and markers of oxidative metabolism (pgc1α, cpt1a, cs, nd2, cox1), mitochondrial respiration uncoupling (ucp3) and fatty acid and triglyceride metabolism (pparα, pparγ, elovl5, scd1a, lpl, atgl) that were specific to each strain and tissue. The anterior intestine of the fast-growing strain was better suited to cope with improved growth by increased expression of markers of nutrient absorption (fabp2), epithelial barrier integrity (cdh1, cdh17) and immunity (il1β, cd8b, lgals1, lgals8, sIgT, mIgT), which were correlated with low expression levels of sirt4 and markers of fatty acid oxidation (cpt1a). In the posterior intestine, the fast-growing strain showed a consistent up-regulation of sirt2, sirt3, sirt5 and sirt7 concurrently with increased expression levels of markers of cell proliferation (pcna), oxidative metabolism (nd2) and immunity (sIgT, mIgT). Together, these findings indicate that SIRTs may play different roles in the regulation of metabolism, inflammatory tone and growth in farmed fish, arising as powerful biomarkers for a reliable metabolic phenotyping of fish at the tissue-specific level.

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Section: Discussionsupporting

confidence: 85%

Section: Discussionmentioning

confidence: 99%

Co-expression Analysis of Sirtuins and Related Metabolic Biomarkers in Juveniles of Gilthead Sea Bream (Sparus aurata) With Differences in Growth Performance

et al. 2018

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“…A decreased feed intake has been observed in some fish feeding trials with diets containing MCFA (Nordrum, Olli, Rosjo, Holm, & Krogdahl, ; Williams et al, ), but not in others (Figueiredo‐Silva et al, ; Hamre et al, ; Simó‐Mirabet et al, ). An increase in dietary MCT (as 8:0 and 10:0 (50:50) up to 46% of total fat) decreased the feed intake with up to 40% in Atlantic salmon, also severely affecting growth performance (Nordrum et al, ).…”

Section: Discussionmentioning

confidence: 95%

Insect-based diets high in lauric acid reduce liver lipids in freshwater Atlantic salmon

et al. 2018

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We evaluated the effect of a diet containing insect meal and insect oil on nutrient utilization, tissue fatty acid profile and lipid metabolism of freshwater Atlantic salmon (Salmo salar). Insect meal and insect oil from black soldier fly larvae (Hermetia illucens, L.; BSF), naturally high in lauric acid (12:0), were used to produce five experimental diets for an eight-week feeding trial. 85% of the dietary protein was replaced by insect meal and/or all the vegetable oil was replaced by one of two types of insect oil.A typical industrial diet, with protein from fishmeal and soy protein concentrate (50:50) and lipids from fish oil and vegetable oil (33:66), was fed to a control group.The dietary BSF larvae did not modify feed intake or whole body lipid content.Despite the high content of saturated fatty acids in the insect-based diets, the apparent digestibility coefficients of all fatty acids were high. There was a decrease in liver triacylglycerols of salmon fed the insect-based diets compared to the fish fed the control diet. This is likely due to the rapid oxidation and low deposition of the medium-chain fatty acid lauric acid. K E Y W O R D SAtlantic salmon, black soldier fly, fatty acid oxidation, lauric acid, lipid metabolism, mediumchain FA S U PP O RTI N G I N FO R M ATI O NAdditional supporting information may be found online in the Supporting Information section at the end of the article. How to cite this article: Belghit I, Waagbø R, Lock E-J, Liland NS. Insect-based diets high in lauric acid reduce liver lipids in freshwater Atlantic salmon. Aquacult Nutr. 2019;25:343-357.

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“…piscicida or the intestinal parasite Enteromyxum leei (Piazzon et al., ). Experimental evidence also indicates that diets enriched in dietary sodium dodecanoic acid salt enhance feed intake and growth rates in gilthead sea bream juveniles (Simó‐Mirabet et al., ), but to our knowledge, there is no information about the potential benefits of synthetic C7‐carboxylic acid salts in fish and gilthead sea bream in particular. Taking into consideration the putative impact of SCFA and MCFA supplementation reported on fish and other animal production systems, the aim of this study is to explore the potential benefits of a commercial preparation of sodium heptanoate salt in a factorial design (2 × 2) with standard or low inclusion levels of fish meal (FM) as dietary protein source.…”

Section: Introductionmentioning

confidence: 99%

Dietary sodium heptanoate helps to improve feed efficiency, growth hormone status and swimming performance in gilthead sea bream (Sparus aurata)

et al. 2018

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The potential benefits of a commercial preparation of heptanoate (NOREL, HEPTON®) were evaluated in an 11‐week gilthead sea bream feeding trial (May–August), using a factorial design with four isoproteic and isoenergetic diets. Fish meal (FM) was added at 200 g/kg in D1–D2 diets and at 50 g/kg in D3–D4 diets, which also contained fish peptones and plant proteins as source of proteins. Heptanoate was added at 3 g/kg in D2 and D4 diets. All fish grew from 13–14 g to 81–84 g with an overall feed efficiency (FE) of 0.91–0.94. An early impairment of FE (weeks 1–4) was found with the standard FM‐based diet (D1), but this detrimental condition was reversed by heptanoate, increasing FE from 0.88 in D1 fish to 0.99 in D2 fish. Further improvements were progressively diluted over time, remaining D2 and D3–D4 fed fish almost undistinguishable through all the trial. Heptanoate supplementation produced higher hepatic glycogen depots, but no signs of histopathological damage were found in liver or intestine. Other lasting heptanoate effects included changes in plasma antioxidant capacity, plasma cortisol and growth hormone levels, and measures of respirometry in swimming performance tests. Altogether, it supports the potential use of heptanoate to speed up adaptive and healthy metabolic states of farmed fish to cope with challenging culture conditions.

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Sodium salt medium-chain fatty acids andBacillus-based probiotic strategies to improve growth and intestinal health of gilthead sea bream (Sparus aurata)

Cited by 42 publications

References 72 publications

Co-expression Analysis of Sirtuins and Related Metabolic Biomarkers in Juveniles of Gilthead Sea Bream (Sparus aurata) With Differences in Growth Performance

Co-expression Analysis of Sirtuins and Related Metabolic Biomarkers in Juveniles of Gilthead Sea Bream (Sparus aurata) With Differences in Growth Performance

Insect-based diets high in lauric acid reduce liver lipids in freshwater Atlantic salmon

Dietary sodium heptanoate helps to improve feed efficiency, growth hormone status and swimming performance in gilthead sea bream (Sparus aurata)

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