URI
researchers awarded multiple grants to study oyster genetics, breeding,
diseases in support of aquaculture industry
 |
| Photo from RI Sea Grant program at URI |
“Wild and farmed oysters are facing
major threats from water quality and disease,” said Marta Gomez-Chiarri, a URI
professor of animal science who has studied oyster diseases in Narragansett Bay
for more than 20 years.
“Even though local water quality has improved in Rhode Island, oysters across the United States face localized threats from pollution and eutrophication while at the same time dealing with multiple factors of global ocean change, like ocean acidification, as well as changes in salinity and dissolved oxygen. We are only beginning to understand the effects of these multiple stressors.”
“Even though local water quality has improved in Rhode Island, oysters across the United States face localized threats from pollution and eutrophication while at the same time dealing with multiple factors of global ocean change, like ocean acidification, as well as changes in salinity and dissolved oxygen. We are only beginning to understand the effects of these multiple stressors.”
Gomez-Chiarri – along with URI
Assistant Professor Jonathan Puritz and U.S. Department of Agriculture
scientist Dina Proestou – have teamed with shellfish geneticists and breeders
from 10 other East Coast universities to form the Eastern Oyster Genome
Consortium to develop genetic tools to accelerate selective breeding efforts.
The consortium, in a proposal led by Rutgers University, has been awarded a $4.4 million grant from the Atlantic States Marine Fisheries Commission to accelerate the pace of identifying the genes responsible for desirable traits like disease resistance.
The consortium, in a proposal led by Rutgers University, has been awarded a $4.4 million grant from the Atlantic States Marine Fisheries Commission to accelerate the pace of identifying the genes responsible for desirable traits like disease resistance.
“We know that the oyster is very adaptable, so we’re trying to determine the genetic signatures of traits like disease resistance or tolerance for high temperatures or low salinity,” said Gomez-Chiarri.
“But we also want to figure out what makes an oyster survive in Maine versus in the Gulf of Mexico where conditions are so different. We want to develop genetic strains that are adapted to each region. This grant will help us figure out the genetic tools to inform breeding so we can understand how to improve oysters from different regions and make them resilient to the threats in that region.”
“By leveraging new developments in
genomics, we are in a good position to apply new and existing breeding
technologies to additional locations more efficiently,” added Proestou. “This
will help growers by providing them with selected oyster stocks that are
well-suited to specific growing environments.”
The URI researchers are also
approaching the problem of oyster disease from another direction. They have
received four grants to study how probiotics may be used to manage diseases in
oyster aquaculture facilities.
One project, funded with two grants
totaling $867,000 from the U.S. Department of Agriculture to Professors David
Nelson, David Rowley and Gomez-Chiarri, is examining the basic mechanisms of
how probiotics work in oysters.
“It’s biological warfare between
bacteria,” Nelson explained.
“Both the pathogen and probiotic have genes that encode mechanisms that allow each organism to successfully compete with and even kill its competitors when they interact. We’re trying to determine the arsenal of weapons that each bacterium has and how they use them against each other. This knowledge will allow us to better understand how we can use probiotic bacteria to protect oyster larvae from pathogenic bacteria.”
“Both the pathogen and probiotic have genes that encode mechanisms that allow each organism to successfully compete with and even kill its competitors when they interact. We’re trying to determine the arsenal of weapons that each bacterium has and how they use them against each other. This knowledge will allow us to better understand how we can use probiotic bacteria to protect oyster larvae from pathogenic bacteria.”
This investigation also examines the
molecular mechanisms of virulence used by the pathogenic bacteria to attack the
oysters.
A $300,000 grant from the National
Oceanic and Atmospheric Administration will enable Nelson, Rowley and
Gomez-Chiarri to work with companies to commercialize a probiotic they discovered
through previous laboratory studies.
They will work to scale up production of the probiotic and conduct hatchery trials to determine its effectiveness at combatting disease in a commercial setting.
They will work to scale up production of the probiotic and conduct hatchery trials to determine its effectiveness at combatting disease in a commercial setting.
Another $300,000 grant from the USDA
will allow URI researchers to evaluate how a probiotic affects the microbial
community throughout an oyster hatchery.
“We’ll be looking at all the
microbes in the hatchery and how the probiotics interact with those in the
water and in the larvae and on the surfaces of the tanks,” Gomez-Chiarri said.
“Each tank is a world of microbes all its own.”
In addition, the USDA’s National
Institute of Food and Agriculture provided workforce development grants to
former Postdoctoral Fellow Tal Ben Horin and current graduate student Erin
Roberts to conduct studies of oyster disease resistance. And the Narragansett
Bay Shellfish Restoration Foundation has provided support to several graduate
and undergraduate students performing research geared to oyster restoration in
Narragansett Bay.
“All of this work is aimed at trying
to help the aquaculture and fisheries industries and the marine environment,”
said Gomez-Chiarri.
“Oysters are so very important for the ecosystem services they provide, so we’re trying to understand more about them, from their genetics to their microbes to how they live and survive in the environment. It’s all to understand better what they provide to us and how we can better manage the population.”
“Oysters are so very important for the ecosystem services they provide, so we’re trying to understand more about them, from their genetics to their microbes to how they live and survive in the environment. It’s all to understand better what they provide to us and how we can better manage the population.”
