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Mussels Cramped by Environmental Factors

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The fibrous threads helping mussels stay anchored – in spite of waves that sometimes pound the shore with a force equivalent to a jet liner flying at 600 miles per hour – are more prone to snap when ocean temperatures climb higher than normal.

Emily Carrington, a University of Washington professor of biology, reported Saturday (Feb. 16) that the fibrous threads she calls “nature’s bungee cords” become 60 percent weaker in water that was 15 degrees F (7 C) above typical summer temperatures where the mussels were from. She spoke at the American Association for the Advancement of Science meeting in Boston.

“Conditions that harm mussel populations affect commercial growers and, because mussels are at the foundation of the marine food web, also deprive predators such as crabs, lobsters and sea anemones of food,” Carrington said.

Mussels anchor themselves in place using masses of strong, flexible byssal threads. Pictured is Mytilus trossulus, the bay mussel exposed to a a range of temperatures in University of Washington experiments. Image credit: E Carrington/Friday Harbor Laboratories/UW

Mussels anchor themselves in place using masses of strong, flexible byssal threads. Pictured is Mytilus trossulus, the bay mussel exposed to a a range of temperatures in University of Washington experiments. Image credit: E Carrington/Friday Harbor Laboratories/UW

Such research might one day help natural resources managers in Washington, where Carrington’s work was done, and elsewhere estimate future abundance correctly and recognize areas with conditions most favorable to mussel survival. It might lead commercial growers to breed resistant varieties or be on the lookout to invest in the most promising locations for the future.

Carrington was the sole environmental biologist on a panel at the American Association for the Advancement of Science symposium on how to develop adhesives similar to mussels.

“Certainly spider silk is the darling of the biomaterials world because of its high strength. But the spotlight is getting brighter for mussels because they make strong, tough, durable attachments that can set underwater,” Carrington said.

“What biologists can contribute to the materials science arena is an appreciation of biodiversity,” she said. “Mussels live in all kinds of habitats. Some species are experts at gluing onto sea grass, some to other shells, some even adhere in the harsh conditions of hydrothermal vents. They each may have different genes that code for different proteins so the adhesive will be a little different and worth exploring.”

UW researchers Matt George, Michael O’Donnell and Rebecca Guenther measure water chemistry during an experiment exposing mussels to varying sets of conditions at the University of Washington’s Friday Harbor Laboratories. Image credit: K Ballard/Friday Harbor Laboratories/UW

UW researchers Matt George, Michael O’Donnell and Rebecca Guenther measure water chemistry during an experiment exposing mussels to varying sets of conditions at the University of Washington’s Friday Harbor Laboratories. Image credit: K Ballard/Friday Harbor Laboratories/UW

Mussels form attachments to rocks, fellow mussels and other surfaces with what’s called the byssus, a mass of golden-colored threads or filaments. Although each strand is only three to 10 times the width of a human hair, the threads are extraordinarily strong and stretchy, she says.

That’s good, given the forces at work where mussels live in the intertidal zone, the part of the shore covered by water when the tide is in and high and dry when it’s out.

Carrington says a modest wave on the outer coast of Washington clips along at 10 meters per second.

“An inland stream with water moving at only one meter per second is very hard to stand in,” she said. “Imagine something going 10 times that speed – over your whole body.”

Carrington calculates that wind would have to blow 600 miles per hour to generate the same force as water traveling 10 meters per second.

A mussel suspended in a University of Washington laboratory has already created one byssal thread and is reaching out its foot to mold a second strong, flexible thread. Mussels typically create 50 threads to anchor themselves in place. Image credit: L Coutts/Friday Harbor Laboratories/UW

A mussel suspended in a University of Washington laboratory has already created one byssal thread and is reaching out its foot to mold a second strong, flexible thread. Mussels typically create 50 threads to anchor themselves in place. Image credit: L Coutts/Friday Harbor Laboratories/UW

Carrington’s work, based at the UW’s Friday Harbor Laboratories and funded by the National Science Foundation, involves field observations of natural populations that she and her team try to repeat in the laboratory. In the lab they change one factor at a time – considering such stressors as temperature and ocean acidification – to understand which of many possible environmental culprits are most important, she said.

For example in lab experiments led by UW doctoral student Laura Newcomb, the strength of byssal threads formed in water at 77 degrees F (25 C) were 60 percent weaker compared to those formed at 50 F and 65 F (10 C and 18 C). The waters in the natural habitat around Friday Harbor Laboratories is typically 50-54 F (12-14 C) in the summer, she said, although in places like shallow bays it can be much higher.

Scientists have previously found that the byssus weakens naturally in late summer and early fall. When autumn hurricanes and storms hit, both wild and commercially farmed mussels are then more prone to “fall off.” In work she did on the U.S. east coast, for example, the early storms of fall wiped one third of the mussels from where they’d been attached. Even winter’s nor’easters cause less fall off because the byssus by then has regained strength.

“We’re trying to learn what causes this seasonal weakening – is it related to warmer weather, their spawning cycle or something else,” she said. “And now we want to know if increased environmental fluctuations will help put them over the edge.”

“The mussel is a keystone species in rocky intertidal areas,” says David Garrison, director of the National Science Foundation’s Biological Oceanography Program, which funded the research. “Detachment of mussels results in lost habitat for myriad other organisms.”

– By Sandra Hines

*Source: University of Washington

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