Posidonia seagrass meadows, veritable underwater forests, play a major ecological role. Under constant pressure from human activity, scientists are looking for ways to ensure their survival, in particular by carrying out restoration campaigns. A study conducted by the University of Liège at the marine and oceanographical research station STARESO (Calvi,
Posidonia seagrass meadows, veritable underwater forests, play a major ecological role. Under constant pressure from human activity, scientists are looking for ways to ensure their survival, in particular by carrying out restoration campaigns. A study conducted by the University of Liège at the marine and oceanographical research station STARESO (Calvi, Corsica) reveals that the transplantation method directly influences the root microbiome, which is essential for the survival of the plants. These results pave the way for more effective and sustainable restoration techniques. The paper is published in the journal Environmental Microbiome. Roots growing on a Posidonia cutting transplanted using metal staples. Arnaud Boulenger conditioning Posidonia roots for genetic analysis of the microbiome. Credit: University of Liège, Arnaud Boulenger Often compared to terrestrial forests, Posidonia oceanica seagrass meadows form off the coast of the Mediterranean. These ecosystems act as environmental sentinels, stabilizing the seabed, storing carbon, and harboring exceptional biodiversity. Unfortunately, scientists have been observing a decline in their population for many years due to coastal urbanization, boat anchoring, and climate change. To halt this decline, researchers are experimenting with transplanting cuttings. “Until now, efforts have focused mainly on their visible survival, i.e., root recovery and leaf growth,” explains Arnaud Boulenger, a Ph.D. candidate in oceanography at ULiège (Belgium). “However, the study we conducted at STARESO reveals that the health of seagrass beds also depends on an invisible network of microorganisms associated with the roots.” It is therefore not enough to simply replant the seagrass meadows; we must also ensure the good health of their microbiome. By testing three transplantation techniques—metal staples, coconut fiber mats and potato starch structures—the team showed that the choice of substrate profoundly changed the composition of the microbiome. “Staples, which allow direct contact with the sediment, promote the establishment of key bacteria such as Chromatiales and Desulfobacterales, which are essential for the sulfur and nitrogen cycles,” the researcher explains. “Conversely, the other methods delay this beneficial colonization.” Scientists highlight that restoration methods must now incorporate this microbiological dimension, as these bacteria play a direct role in plant resilience. “These results are groundbreaking,” says Sylvie Gobert, oceanographer. “This is the first time that a study has demonstrated in situ the importance of the microbiome in the success of Posidonia transplantation. The results we have obtained open up concrete perspectives, such as the inoculation of beneficial bacteria or the design of supports that facilitate root-sediment interaction.” Restoring a seagrass bed is therefore much more than just replanting cuttings underwater. It means recreating an entire ecosystem, both visible and invisible, in which bacteria play a crucial role. As Boulenger sums it up, “it’s a bit like replanting a forest, while also ensuring that the soil that nourishes it is brought back to life.” More information: This article is republished from PHYS.ORG and provided by the University of Liège. Arnaud Boulenger et al, Microbiome matters: how transplantation methods and donor origins shape the successful restoration of the seagrass Posidonia oceanica, Environmental Microbiome (2025). DOI: 10.1186/s40793-025-00764-9
