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                      Natural algal communities can inhibit aquaculture pathogens

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                      In aquaculture, antibiotic resistance is increasingly becoming a problem. Since fish larvae lack a developed immune system, vaccines are ineffective against them and so alternative techniques are needed. Researchers from the EU-funded MARBLES project at the Technical University of Denmark (DTU) have demonstrated that bacteria derived from live-feed microalgae are capable of inhibiting fish pathogenic bacteria.

                      The new study by Danish researchers has demonstrated that it is possible to develop a consortium of bacteria that can inhibit bacterial pathogens in aquaculture. This could potentially reduce the use of antibiotics in aquaculture and possibly other applications. The study was published in Microbiology Spectrum, a journal of the American Society for Microbiology. In the new study, researchers set out to find and develop non-antibiotic biological disease control and prevention options for aquaculture. Aquaculture is the fastest growing food-protein producing sector in the world, and the carbon footprint is lower than that of many animal husbandry sectors. Aquaculture, like other intensive productions, is challenged by infectious disease outbreaks. Most commonly, these are caused by bacterial agents and can, to some extent, be treated with antibiotics. However, the alarming rise and spread of antibiotic-resistant bacteria calls for alternative treatments. While vaccines can be an excellent strategy, these do not work on fish larvae that have no developed immune system. Using beneficial bacteria or probiotics to combat pathogens is a strategy becoming widespread in both animal rearing and horticulture.

                      The researchers developed an in vitro assay to evaluate the anti-pathogen efficacy of mixed algal microbiomes from the live-feed microalgae Tetraselmis suecica and Isochrysis galbana. The scientists wanted to find combinations of beneficial bacteria, since they believe that the anti-pathogen effect is likely stronger in a combination.

                      “To test if the pathogen could be inhibited by a mixture of other bacteria, we needed a measure of the growth (and growth inhibition of the pathogen), so we tagged the fish pathogen with a green fluorescent protein. By measuring this—and the reduction in fluorescence— we could identify bacterial communities that inhibited the pathogen,” said corresponding study author Lone Gram, Ph.D., professor in the Department of Biotechnology and Biomedicine, DTU.

                      The researchers found that mixtures of bacteria could inhibit Vibrio anguillarum, a fish pathogen, and subsequently isolated pure cultures of bacteria. They found that some of these bacteria only inhibited the fish pathogen when combined, not alone, demonstrating that some bacteria were stronger together.

                      “We have shown that it is possible in microbiomes (in our case, the microbiome of algae used as live feed in aquaculture) to find mixtures of bacteria that can inhibit the pathogen,” Gram said, “thus paving the way for engineering microbiomes that can inhibit bacterial pathogens and reduce the need for use of antibiotics. We can then reduce the spread of antibiotic-resistant bacteria.”

                      To learn more about the research, you can read the MARBLES open access publication: Smahajcsik, D., Roager, L., Strube, M. L., Zhang, S., & Gram, L. (2025). Stronger together: harnessing natural algal communities as potential probiotics for inhibition of aquaculture pathogens. Microbiology Spectrum. DOI: https://doi.org/10.1128/spectrum.00421-25.

                      MARBLES (Marine Biodiversity as Sustainable Resource of Disease-Suppressive Microbes and Bioprotectants for Aquaculture and Crop Diseases) is a research and innovation action funded by Horizon 2020 (Grant Agreement no. 101000392). With 14 partners from 10 countries, the project runs for four years until April 2026 and has a total budget of €7.5 million. MARBLES is coordinated by Leiden University in the Netherlands.

                      This press release was originally published by the American Society for Microbiology (ASM). ASM is one of the largest professional societies dedicated to the life sciences and is composed of over 37,000 scientists and health practitioners. Their mission is to promote and advance the microbial sciences.

                      • For more information on this research please contact Lone Gram (Technical University of Denmark) gram@bio.dtu.dk.
                      • For more information on the MARBLES project please visit the project website, follow us on LinkedIn: MARBLES EU Project and X: MARBLES_EU
                      • Project Communications: Avril Hanbidge (ERINN Innovation) avril@erinn.eu
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                      This project has received funding from the European Union’s Horizon 2020 research and innovation programme under Grant Agreement no. 101000392 (MARBLES). This output reflects only the author’s view and the European Research Executive Agency (REA) cannot be held responsible for any use that may be made of the information contained therein.

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