Trossulus byssus mussels. Scientists from the University of Washington have found evidence that ocean acidification caused by carbon emissions can prevent mussels attaching themselves to rocks and other substrates, making them easy targets for predators and threatening the mussel farming industry. Photo: Emily Carrington

6 July 2016 (Society for Experimental Biology) – Scientists from the University of Washington have found evidence that ocean acidification caused by carbon emissions can prevent mussels attaching themselves to rocks and other substrates, making them easy targets for predators and threatening the mussel farming industry.

“A strong attachment is literally a mussel’s lifeline,” said UW biology professor Emily Carrington, who presented these findings July 6 at a meeting of the Society for Experimental Biology.

Mussels attach themselves to hard surfaces so that they can filter plankton from seawater for food. They generally live in tidal zones, where the strong waves and currents protect them from predators such as crabs, fish and sea stars. But if a mussel falls off its perch, it sinks down into calmer waters where it is readily eaten.

Future conditions may make it more difficult for mussels to attach themselves and stay out of harm’s way. This is because the pH level appears to be critical during the attachment process, and our oceans are becoming more acidic from absorbing CO2 emissions from the atmosphere.

“Our early laboratory studies showed mussels made weaker attachment threads when seawater pH dropped below 7.6,” said Carrington, who is based primarily at UW’s Friday Harbor Laboratories.

These results could have severe implications for aquaculture. In mussel farms, the mussels attach themselves to ropes suspended in the water for six to 12 months while they grow to market size. Currently, weak attachments can cause up to 20 percent of the crop to fall off and be lost on the seafloor.

The researchers have shown that the change in pH specifically affects the adhesive plaque which cements the mussel to the underlying surface.

“We investigated whether lowering seawater pH would affect the curing process of the attachment threads,” said Carrington.

Threads made by mussels in seawater with a “normal” pH of 8 were then kept at either pH 8, 7 or 5 to cure for 12 days. Using a materials testing machine, the team found that threads cured at the lower pH values were 25 percent weaker than the controls.

“We conclude that mussels rely on the high pH of seawater to cure their adhesive effectively and form strong attachments,” said Carrington.

Furthermore, one mussel species, Mytilus trossulus, also made fewer and weaker threads when the temperature of the water was increased above 64°F. In contrast, a closely related non-native species, Mytilus galloprovincialis, made more and stronger threads. This suggests warming oceans will increasingly favor the non-native species, allowing it to expand its distribution polewards and push out native species.

Although the global average ocean pH is only predicted to lower from 8.0 to 7.8 by the end of the century, this could still have a profound effect on mussel communities, says Carrington.

“Due to upwelling and local productivity, our seawater in Washington is already at a baseline of pH 7.8,” said Carrington. “Moreover, mussels live in highly dynamic coastal environments that routinely fluctuate up or down 0.5 pH units.”

This means that mussels are already exposed at times to conditions that weaken attachment and these periods may be longer and more severe in the future.

Carrington’s colleagues on this study include UW doctoral student Matthew George, former UW doctoral student and recent graduate Laura Newcomb, Ian Jefferds with Penn Cove Shellfish, UW professor of aquatic and fishery sciences Carolyn Friedman and former UW researcher Michael O’Donnell, who is now with the University of California.

The research was funded by Washington Sea Grant.

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For more information, contact Emily Carrington at ecarring@uw.edu.

Adapted from a release by the Society for Experimental Biology.

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