As the human population surges towards 10 billion, the production and consumption of aquaculture products such as fish is expanding. Efficient and environmentally sustainable practices are therefore required to ensure long-term food security. One promising route to achieve this, is to unravel the functional connection between what the fish eat, the gut microbial function, and ultimately, how this influence fish health and aquaculture production. Our new project ImprovAFish will therefore adopt a strategy to collectively study the animal, its diet and all its microbes as one unit (the holobiont) in Atlantic salmon. The project will use state-of-the-art methods that enables us to measure these interactions at the molecular level (genes and enzymes). In our experiments we will use a promising 'next generation' functional feed ingredient (beta-mannan) that is known to promote beneficial microbiota in production animals, including promising preliminary data in fish. In addition, we will investigate if the genetic make-up of individual fish can influence gut microbial composition, knowledge that could facilitate targeted breeding for fish with good gut microbes. The aim of ImprovAFish is to expand our understanding of the feed-microbe-salmon axis and improve sustainability of aquaculture.
As the human population surges towards 10 billion, the production and consumption of aquaculture products such as fish is expanding. Efficient and environmentally sustainable practices are therefore required to ensure long-term food security. To solve these challenges, attractive solutions include developing new feed ingredients and better broodstock genetics to improve fish production and welfare. Intriguingly, it has been shown that both feed and host genetics can modulate the microbiome of animals and thus influence its integral connection to host phenotype. The ambitious aim of ImprovAFish is to decipher the intimate functional coupling along the feedmicrobiome-host axis in an applied context, with the emphasis on a promising 'next generation' functional feed ingredient (beta-mannan) that is known to promote beneficial microbiota in production animals, including promising preliminary data in fish.
Our approach is to jointly analyze how diet affects the metabolic function of the host and its microbiome as a single unit of action, using a novel and powerful framework called 'holo-omics'. This entails monitoring how changes in enzymes and metabolites produced by microbiota, correlates with uptake and metabolism of nutrients in the gut and liver of the fish. By doing this across life stages, different feeds and with recordings of key performance indices, we aim to identify exploitable interactions between specific feed components and microbiome functions that can be used to improve fish phenotype. In addition, associations between broodstock genetic variation, microbiome composition and diet will be determined, which will facilitate selection for fish with preferred gut microbiota. Ultimately ImprovAFish will facilitate optimization of improved and sustainable feeding strategies that are specifically tailored to host genetics (or vice versa), with an emphasis on socially responsible outcomes facilitated by a dedicated Responsible Research and Innovation process.