Oyster
aquaculture limits disease in wild oyster populations
A fisheries researcher at the
University of Rhode Island has found that oyster aquaculture operations can
limit the spread of disease among wild populations of oysters. The findings are
contrary to long-held beliefs that diseases are often spread from farmed
populations to wild populations.
“The very act of aquaculture has
positive effects on wild populations of oysters,” said Tal Ben-Horin, a
postdoctoral fellow at the URI Department of Fisheries, Animal and Veterinary
Sciences in the College of the Environment and Life Sciences.
“The established way of thinking is that disease spreads from aquaculture, but in fact aquaculture may limit disease in nearby wild populations.”
“The established way of thinking is that disease spreads from aquaculture, but in fact aquaculture may limit disease in nearby wild populations.”
Working with colleagues at the University of Maryland Baltimore County, Rutgers University, the U.S. Department of Agriculture, and the Virginia Institute of Marine Science, Ben-Horin integrated data from previous studies into mathematical models to examine the interactions between farmed oysters, wild oysters and the common oyster disease Dermo.
Their research, part of a synthesis
project at the National Center for Ecological Analysis and Synthesis, was
published this week in the journal Aquaculture Environment Interactions.
According to Ben-Horin, diseases are
among the primary limiting factors in wild oyster populations. There are few
wild populations of oysters in New England because of Dermo and other diseases,
and in the Chesapeake Bay and Delaware Bay, wild oysters are managed with the
understanding that most will die from disease.
Dermo is caused by a single-celled
parasite that occurs naturally in the environment and proliferates in the tissue
of host oysters, which spread the parasite to other oysters when they die and
their parasite-infected tissues decay in the water column. But it takes two to
three years for the parasite to kill the oysters.
As long as the oysters are held on farms long enough to filter disease-causing parasites from the water, but not so long that parasites develop and proliferate and spread to wild oysters nearby, aquaculture operations can reduce disease in wild populations.
As long as the oysters are held on farms long enough to filter disease-causing parasites from the water, but not so long that parasites develop and proliferate and spread to wild oysters nearby, aquaculture operations can reduce disease in wild populations.
The disease does not cause illness
in humans.
“As long as aquaculture farmers
harvest their product before the disease peaks, then they have a positive
effect on wild populations,” Ben-Horin said. “But if they’re left in the water
too long, the positive effect turns negative.”
He said that several factors can
confound the positive effect of oyster aquaculture. Oyster farms that grow
their product on the bottom instead of in raised cages or bags, for instance,
are unlikely to recover all of their oysters, resulting in some oysters
remaining on the bottom longer. This would increase rather than reduce the
spread of the disease.
“But when it’s done right,
aquaculture can be a good thing for wild oyster populations,” Ben-Horin said.
“Intensive oyster aquaculture – where oysters are grown in cages and growers
can account for their product and remove it on schedule – is not a bad thing
for wild populations.”
The study’s findings have several
implications for the management of wild and farmed oysters.
Ben-Horin recommends establishing best management practices for the amount of time oysters remain on farms before harvest. He also suggests that aquaculture managers consider the type of gear – whether farmers hold oysters in cages and bags or directly on the seabed – when siting new oyster aquaculture operations near wild oyster populations.
Ben-Horin recommends establishing best management practices for the amount of time oysters remain on farms before harvest. He also suggests that aquaculture managers consider the type of gear – whether farmers hold oysters in cages and bags or directly on the seabed – when siting new oyster aquaculture operations near wild oyster populations.
The next step in Ben-Horin’s
research is to gain a better understanding of how far the Dermo parasite can
spread by linking disease models with ocean circulation models.
“Everything that happens in the
water is connected. There’s a close relationship between the wild and farmed
oyster populations and their shared parasites,” he said. “Sometimes ecosystem
level effects are overlooked, but in this case they’re front and center.”
Study co-author Ryan Carnegie of the
Virginia Institute of Marine Science said this research is an important
contribution to the dialogue about the interactions between shellfish
aquaculture and the environment.
“It’s critical that we fully
appreciate how aquaculture fits in the ecology of marine systems, and this
study provides new perspective on this,” he said. “It highlights an important
ecological benefit that intensive shellfish aquaculture may provide. This
should help bolster the well-justified public perception of shellfish
aquaculture as a green industry worthy of their support, which this industry
must have if it is to grow.”
