Physiological Benefits of Dietary Lysophospholipid Supplementation in a Marine Fish Model: Deep Analyses of Modes of Action

Given the hydrophilic structure of lysophospholipids (LPLs), their dietary inclusion translates into a better emulsifying capacity of the dietary components. The present study aimed to understand the mechanisms underlying the growth-promoting effect of LPL supplementation by undertaking deep analyses of the proximal intestine and liver interactomes. The Atlantic salmon (Salmo salar) was selected as the main aquaculture species model. The animals were divided into two groups: one was fed a control diet (C-diet) and the other a feed (LPL-diet) supplemented with an LPL-based digestive enhancer (0.1% AQUALYSO®, Adisseo). The LPL-diet had a positive effect on the fish by increasing the final weight by 5% and reducing total serum lipids, mainly due to a decrease in the plasma phospholipid (p < 0.05). In the intestine, the upregulated interactome suggests a more robust digestive capacity, improving vesicle-trafficking-related proteins, complex sugar hydrolysis, and lipid metabolism. In the liver, the LPL-diet promotes better nutrients, increasing several metabolic pathways. The downregulation of the responses to stress and stimuli could be related to a reduced proinflammatory state. This study on the benefits and modes of action of dietary LPLs opens a new window into fish nutrition and could be extended to other productive species.info:eu-repo/semantics/publishedVersio

A novel fish meal-free diet formulation supports proper growth and does not impair intestinal parasite susceptibility in gilthead sea bream (Sparus aurata) with a reshape of gut microbiota and tissue-specific gene expression patterns

The exponential growth of the aquaculture sector requires the development of sustainable aquafeeds with less dependence on marine products. The maximized replacement of fish meal (FM) and fish oil (FO) with plant ingredients has been extensively studied in the economically important species gilthead sea bream (Sparus aurata). Recently, major progress has been done with other alternative raw materials, though some non-pathological inflammatory response persisted with feed formulations that increased the circularity of resource utilization. In the present study, we evaluated the effects on growth performance, gene expression, intestinal microbiota and disease resistance of a FM-free diet (NoPAP SANA), based on plant ingredients, aquaculture by-products, algae oil, insect meal and bacterial fermentation biomasses as main dietary oil and protein sources, and supplemented with a commercially available health-promoting feed additive (SANACORE®GM). Juveniles of 21 g initial body weight were fed control or NoPAP SANA diets for 34 days, and head kidney, liver and posterior intestine were collected for gene expression analyses using customized PCR-arrays. Each tissue-specific PCR covered 96 genes in total and included markers of growth performance, lipid and energy metabolism, antioxidant defence, immune system, and intestinal function and integrity. From the same fish, the adherent bacteria of the posterior intestine were studied by Illumina sequencing of the V3-V4 region of the 16S rRNA. The remaining fish were challenged with the intestinal parasite Enteromyxum leei for 78 days and sampled for parasite diagnosis. Both control and NoPAP SANA fish grew efficiently considering gilthead sea bream standards. Before parasite challenge, the NoPAP SANA group showed differential expression of 17, 2 and 4 genes in liver, head kidney and posterior intestine, respectively. The intestinal bacterial composition showed no major differences in diversity or at the phylum level. However, 29 abundant OTUs significantly changed with the diet. From these, 10 OTUs were significantly correlated with differentially expressed genes in the different target tissues. Inferred metagenome analyses revealed that the altered microbiota with NoPAP SANA diet could account for changes in 15 metabolic pathways. The intensity and prevalence of infection after the parasite challenge did not significantly vary between dietary treatments, and infected fish from both groups showed similar disease outcome. Altogether, these results indicate that the NoPAP SANA diet promoted optimal growth and a healthy condition in gilthead sea bream without affecting susceptibility against the tested intestinal parasite, as often observed with alternative diets following current industry formulations.This project has received funding from the European Union's Horizon 2020 Research and Innovation Programme under grant agreement No 773330 (GAIN, Green Aquaculture Intensification). This publication reflects the views only of the authors, and the European Commission cannot be held responsible for any use which may be made of the information contained therein. Additional funding was obtained by a Spanish MICINN project (Bream-AquaINTECH, RTI2018–094128-B-I00, AEI/FEDER, UE). M.C·P was funded by a Ramón y Cajal Postdoctoral Research Fellowship (RYC2018-024049-I, co-funded by the European Social Fund & ACOND/2020 Generalitat Valenciana)

Fish meal-free diets supplemented with health promoters support optimal growth in gilthead sea bream, with benefitial changes in gene expression, intestinal microbiota and improved intestinal disease recovery

Trabajo presentado en la International Conference & Exposition Aquaculture Europe, celebrada en Funchal, Maderia (Portugal) del 04 al 07 de octubre de 2021.[Introduction]: The exponential growth of the aquaculture sector requires the development of sustainable aquafeeds with less dependence on marine products. Tolerance to fish meal (FM) and fish oil replacement in the economically important gilthead sea bream (Sparus aurata) is being extensively studied with many products emerging as alternative feed ingredients. It has been demonstrated that alternative diets influence the composition of intestinal adherent microbial populations, which have a key role on host metabolism, health and disease resistance. In addition, low fish meal diets showed an increased susceptibility to enteric parasites (Piazzon et al., 2017). Clearly, differences in diet have an impact on the overall health and metabolism of the fish and many parameters have to be taken into account when studying alternative diets for their use in aquaculture. In this study we evaluated the effect of a novel feed formulation (NoPAP SANA) with total replacement of FM by insect meal and bacterial fermentation biomass, and supplemented with the health-promoter additive SANACORE®GM (Palenzuela et al., 2020), on growth performance, gene expression, intestinal microbiota and disease resistance in gilthead sea bream.[Methods]: Tagged gilthead sea bream of mean weight 21.3 g were distributed in two open-flow tanks (160 fish/tank) and fed ad libitum during 34 days with control or NoPAP SANA diets. Twelve fish/diet were sacrificed and head kidney (HK), liver (L) and posterior intestine (PI) were taken for RNA extraction. From the same fish, the adherent bacteria of PI were collected and immediately used for DNA extraction. RNA from HK, L and PI was used to run three customized PCR-arrays including genes of interest for each tissue, with markers of performance and metabolism (L), immune system (HK and PI), epithelial integrity, nutrient transport and mucins (PI). Using the bacterial DNA, the V3-V4 region of the 16S rRNA of each individual sample was amplified and sequenced by Illumina MiSeq. After quality filtering, taxonomic assignment was performed with a custom-made pipeline using the RDP database. Alpha diversity was calculated using Phyloseq and beta diversity using PERMANOVA and PLS-DA models. Metagenome prediction and pathway analysis were performed using Piphillin. Differential gene expression and OTU presence and abundance correlations were studied using the corrplot R package. From the remaining fish, 70 fish/group were challenged with the intestinal parasite Enteromyxum leei by effluent exposure and the remaining fish were used as controls. The challenge lasted 78 days, including a non-lethal diagnosis sampling at day 40. At the end of the challenge all fish were sampled for histological and molecular diagnosis. Biometric values from all fish were taken in all sampling points.[Results]: A slight decrease in condition factor and specific growth rate was detected in the NoPAP SANA group. However, all fish grew efficiently considering gilthead sea bream standards. NoPAP SANA group showed differential expression of 17 out of 44 genes in L, two out of 29 in HK, and 4 out of 44 in PI. The bacterial composition at the PI showed no major differences in diversity or at the phylum level. However, 29 abundant (>1%) OTUs significantly changed with the diet. From these, 10 OTUs were significantly correlated with differential expression of genes in the different tissues, highlighting Pseudoxanthomonas which was positively correlated with the expression of seven L genes, or Actinomyces, significantly correlated with the expression of L and HK genes (Fig. 1). Inferred metagenome analyses revealed that the altered microbiota with NoPAP SANA diet could account for changes in 15 metabolic pathways. The intensity and prevalence of infection after the parasite challenge was not significantly different between diets. In fact, infected fish from both groups showed similar recovery rates.[Conclusions]: NoPAP SANA promoted good growth parameters and efficient conversions arising as a good alternative for a FMbased diet in gilthead sea bream diets. This diet modulated the expression of several genes in L showing the capacity to reduce lipogenesis, mitochondrial activity and the risk of oxidative stress and, at the same time, promoting an antiinflammatory gene expression profile in HK and PI. Changes were also detected in the adherent bacterial populations of PI, with significant changes of OTUs that could potentially account for significant metabolic alterations. The correlations between presence and abundance of intestinal bacteria with changes in gene expression of different tissues, together with the pathway analysis results, show that microbiota changes can have an impact on host metabolism at a systemic level, and vice versa. Clearly, the changes induced by this novel FM-free diet supported an accelerated growth with an overall feed conversion ratio close to 1 and no increased susceptibility against this intestinal parasite, as often observed in studies when replacing a FM-based diet.GAIN (EU-H2020 #773330); RYC2018-024049-I/AEI/10.13039/50110001103

Changes in the arabinoxylan fraction of wheat grain during 1 alcohol production

Laboratory produced DDGS samples were compared with commercial samples from a distillery and a biofuel plant. Changes in structure, solubility and content of arabinoxylan (AX) was determined. The distillation process results in a relative increase of AX content compared to the starting material. The heating and drying processes involved in the production of DDGS lead to an increased solubility and viscosity of water-extractable AX. Production of DDGS results in structural changes to the AX. There is a decrease in 2-and 3-linked arabinose oligosaccharides, that contributes to around a 50% reduction in arabinosylation in DDGS compared with the starting grains. The current study shows that laboratory-scale DDGS provide an accurate representation of the commercial scale and that the AX composition of DDGS is consistently uniform irrespective of starting material. The uniformity of DDGS and thin stillage makes them a good potential source of AX for production of prebiotics or other novel products

Alkaline fractionation and enzymatic saccharification of wheat dried distillers grains with solubles (DDGS)

The complete utilisation of Dried Distillers Grains with Soluble (DDGS) requires effective pretreatment strategies aiming to increase the enzymatic digestibility of cellulose and improve its conversion to fermentable sugars. To this end, the effect of different NaOH concentrations (0 – 5%, w/v) and temperature (30 – 121 oC) on the fractionation of DDGS to its main components (cellulose, hemicellulose, proteins) was evaluated. As the NaOH concentration and temperature increased, the total sugar content of the pretreated DDGS solids progressively increased to a maximum of ~88%. At 121 oC and 5% NaOH, the DDGS solid residue consisted primarily of glucose (~53%), a 5-fold increase compared to the original DDGS, reflecting the presence of cellulose, and to a lesser extent by xylose (~25%) and arabinose (~10%) reflecting the presence of hemicellulose. Approximately 83% of the initial hemicellulose and 79% of the protein contents were removed into the liquid fraction during alkaline pretreatment. The enzymatic digestibility of the pretreated DDGS solids by the Accellerase® 1500 cellulase enzyme was significantly improved, resulting in a 3.6 fold increase in glucose yield compared to untreated DDGS. Mass balance analysis demonstrated that the proposed process scheme recovers the majority of the key DDGS components (cellulose, hemicellulose, proteins) in an efficient manner with relatively low losses, and provides a viable approach for the valorisation of DDGS

Natural growth promoters in aquaculture practices

The gastrointestinal tract of the aquatic animal is sensitive and responsive to a number of stressing factors, being those common and the cause of disease and poor performance. In order to minimize these negative outcomes and achieve sustainable, safe, and cost-efficient aquaculture practices, nutritionists must focus not only on nutritional specifications but also on promoting gastrointestinal health. In such task, natural growth promoters, as probiotics or organic acids, stand out as a tool to reach an optimal gut flora balance and to stimulate development and integrity of intestinal epithelium