Ocean acidification makes ecologically important seaweed species fragile

"Climate change is resulting in unprecedented changes in terrestrial and aquatic ecosystems through the emission of greenhouse gases, including carbon dioxide," write the authors, who are based at the University of Gothenburg and the KTH Royal Institute of Technology. "Almost a third of that CO₂is taken up by the ocean, which has profound effects on seaweeds."

To test how future ocean acidification conditions will impact fleshy seaweeds, the team grewFucus vesiculosus, a common brown fleshy algae, in water treated with dissolved CO₂for 90 days. They dissolved enough carbon dioxide to mimic the amount of acidification that we expect will be present in 2100, which is almost three times the acidification in today's oceans.

Throughout the experiment, the team observed the seaweed both on a visible level, by measuring how much it grew, and on a microscopic level, by observing tiny changes to its structure. The team also calculated how well the seaweed performed photosynthesis, analyzed its chemical composition, tested its thallus strength (the leaves and stems that make up the core of the seaweed's structure), and watched how the seaweed moved or broke in response to mechanical stress designed to simulate waves (a metric called "drag") in order to see whether it would be at higher risk of damage or detachment in the ocean.

After comparing these metrics with measurements taken fromF. vesiculosusgrown in non-acidified seawater, the team found that the acidification had mixed results. The seaweed grown in acidified water actually grew more, photosynthesized more effectively, and showed no significant increase in drag. However, they also observed that the acidified seaweed had reduced thallus strength, less dense tissues, a more porous structure overall, and lower levels of calcium and magnesium -- important nutrients that contribute to the strength and flexibility of a plant's structure. In general, the acidified seaweed broke more easily and died more often.

“海洋酸化在ti的负面影响ssue structure and breaking strength of seaweeds likeF. vesiculosuscould have drastic effects on coastal ecosystems," write the researchers. "Such changes could lead to an overall decrease in seaweed coverage, with corresponding negative effects on organisms that depend on these habitats for food and shelter."

The team calls for more research to test whether the impacts of ocean acidification are similar for all fleshy seaweeds. "If this proves to be a general mechanism affecting fleshy seaweeds, the expectation is that ocean acidification will have critical structuring effects on rocky-shore ecosystems given how widely distributed and fundamental brown seaweeds are across one-third of the coastlines of the world."

This research was supported by funding from the Swedish Research Council VR and Rådman och Fru Ernst Collianders Stiftelse.