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martes, 17 de junio de 2014

nsf.gov - National Science Foundation - Summer brings crab feasts--and concerns for Chesapeake blue crabs

Infectious diseases play a part in crab population declines

View scientists doing blue crab research on Chesapeake Bay.
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June 17, 2014

The following is part nine in a series on the NSF-NIH Ecology and Evolution of Infectious Diseases (EEID) Program. See parts: one, two, three, four, five, six, seven and eight.

It's almost summer. Seafood restaurants from coast-to-coast are serving platter after platter of steaming crabs, ready for hammering and picking. The supply seems endless, but is it?

Not if we're talking about blue crabs from Chesapeake Bay.

The bay's iconic blue crab population has dropped to levels not seen since before restrictions were placed on the fishery more than five years ago. What's to blame?

A long and, by Mid-Atlantic standards, brutal winter has been fingered as one culprit. In one of the worst die-offs in recent history, more than a quarter of the Chesapeake's blue crabs perished in the frigid waters.

More than cold water to blame

But that's not the only factor, says disease ecologist Jeff Shields of the Virginia Institute of Marine Sciences in Gloucester Point, Va.

"Several commercially important crustacean populations, including blue crabs, have had declines linked to diseases," says Shields. "In most cases, though, the underlying causes have been difficult to pinpoint because crustacean pathogens [infectious agents] aren't very well known."

To help determine what's infecting Chesapeake blue crabs and other crustaceans, the National Science Foundation (NSF) awarded Shields a grant through the joint NSF-NIH Ecology and Evolution of Infectious Diseases Program.

"We know very little about how disease affects populations of marine invertebrates and even less about how disease might interact with other stressors, such as overfishing," says Dave Garrison, director of NSF's Biological Oceanography Program, which also funded the research.

"This study is a major step toward discovering new ways of wisely managing our coastal resources."

One Chesapeake Bay blue crab killer may be a single-celled parasitic dinoflagellate named Hematodinium, a scourge that infects blue crabs and is of concern in fisheries not only in the Chesapeake, but around the world.

Outbreak in the crab pot and the shedding house

The parasite was first reported along the U.S. East Coast in the 1970s and found in the Chesapeake's blue crabs in the 1990s.

In a Hematodinium outbreak, some 50 percent of crabs caught in fishing pots may die. That number jumps to 75 percent in "shedding houses" where crabs molt their shells, then are collected for the soft-shell industry.

"Infection is almost always fatal--for the crabs," says Shields, who adds that the disease isn't harmful to humans.

In a breakthrough for blue crabs, Shields and colleagues recently succeeded in their effort to uncover the life history of Hematodinium.

"Describing the entire life cycle of Hematodinium is an important step toward controlling the infection," says Shields. "With all the parasite's stages in culture in the lab, we can learn when Hematodinium is most infectious."

The biologists made their discovery by looking at many parasite generations over a year-long period.

Answers under a microscope

Through the research, scientists now know that Hematodinium takes some 40 to 50 days to develop. "That matches what we see in the field," he says. "We think infection is linked with blue crabs' molting cycles."

Hematodinium usually infects young crabs. Some 50 to 70 percent of juvenile blue crabs along the Virginia coast carry the pathogen, "and it's prevalent in bays and inlets along the entire U.S. East Coast," says Shields.

The high cost--to the crab population and to the humans that depend on it--comes in the deaths of young blue crabs before they can make their way from coastal spawning grounds to brackish tributaries, where they become large enough to legally catch.

"Imagine a harvest with 50 percent more crabs," says Shields. "The toll exacted by Hematodinium is very clear."

The parasite is after more than blue crabs, however.

"You can't fish out the blue crabs somewhere and hope this pathogen will be gone," says Shields. "It's also in many other crustaceans, including spider crabs, rock crabs and other swimming crabs."

Insights from the bay's shape

Outbreaks of Hematodinium are linked with certain geographic features, such as shallow bays, lagoons and fjords. "Such features are ideal for the growth and spread of pathogens, as they serve to focus transmissive stages or retain them within the system," writes Shields in a paper published in the Journal of Invertebrate Pathology.

Four factors may facilitate epidemics of Hematodinium and other pathogens: relatively "closed" host (crab) populations, with little immigration and emigration of juveniles and adults; bays with restricted water exchange with the open ocean, which hold in pathogens; stressful environmental conditions, such as overfishing and seasonal hypoxia, or "dead zones"; and pathogens that can rapidly multiply.

"The Chesapeake has several of these features," Shields says.

Managing for pathogens

Shields and colleagues are working to understand how Hematodinium is transmitted in wild crustacean populations and at shrimp farms and other aquaculture operations. "We hope to develop 'best practices' for managing, in particular, the Chesapeake's wild blue crabs."

Diseases can have serious effects on commercial fisheries, Shields says. "But there's a perception among resource managers and fishers that diseases aren't important to the fishing industry, or that little can be done to manage them."

Too few fishery models use information like disease prevalence and distribution, according to Shields, and fisheries management decisions often don't consider disease.

"Estimates of disease-induced effects such as mortality or 'negative marketability' can be incorporated into existing models to improve stock assessment and management," Shields writes in the Journal of Invertebrate Pathology.

Disease may be the sleeper in the decline of the Chesapeake Bay blue crab.

Hard-hit by freezing temperatures, low-oxygen waters and overfishing, unless disease is taken into account, believes Shields, the next blue crabs caught may be headed not to your dinner table, but to the crustacean equivalent of the ICU.

--	Cheryl Dybas, NSF (703) 292-7734 cdybas@nsf.gov

Investigators Harry Wang
Kimberly Reece
Jeffrey Shields

Related Institutions/Organizations College of William & Mary Virginia Institute of Marine Science

Related Programs Biological Oceanography

Related Awards #0723662 Ecological Determinants of Hematodinium Epidemics in the American Blue Crab

Total Grants $2,110,161

Related WebsitesNSF Special Report: The Ecology and Evolution of Infectious Diseases:

http://www.nsf.gov/news/special_reports/ecoinf/index.jsp

Chesapeake Bay blue crabs are in decline: How much does disease play a part?
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Domain of the Chesapeake blue crab: salt marshes on the Eastern Shore of the Delmarva Peninsula.
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researchers with crab samples in a boat at sea

researchers with crab samples in a boat at sea

Juvenile blue crabs are collected in shallow seagrass beds, then sorted for transport to the lab.
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Scientists Jeff Shields and Anna Coffey of VIMS pull a crab pot from the water

Scientists Jeff Shields and Anna Coffey of VIMS pull a crab pot and sort crabs into coolers.
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Two mature male blue crabs with the distinctive color of their claws and walking legs.

Two mature male blue crabs with the distinctive color of their claws and walking legs.

Two mature male blue crabs show the distinctive color of their claws and walking legs.
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researcher taking blood from the base of a walking leg of a blue crab using a syringe

researcher taking blood from the base of a walking leg of a blue crab using a syringe

Hemolymph, or blood, is taken from the base of a walking leg of a blue crab.
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the National Science Foundation(NSF),

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viernes, 6 de diciembre de 2013

nsf.gov - National Science Foundation - Wetlands' ability to overcome sea level rise threatened

When do wetlands reach their limit, and how are we lowering that point?

On this tidal marsh in Chesapeake Bay, wetlands and people have co-existed for millennia.
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December 4, 2013

Left to themselves, coastal wetlands can resist rapid sea level rise.

But humans could be sabotaging some of wetlands' best defenses, according to results published in this week's issue of the journal Nature.

Thanks to an intricate system of feedbacks, wetlands are remarkably good at building up soils to outpace sea level rise. The questions are: When do they reach their limit, and how have we lowered that point?

Without human-caused climate change, "we wouldn't be worried about wetlands surviving the rates of sea level rise we're seeing today," says lead paper author Matthew Kirwan of the Virginia Institute of Marine Science and the National Science Foundation (NSF) Virginia Coast Reserve Long-Term Ecological Research (LTER) site.

Virginia Coast Reserve is one of 26 such NSF LTER sites around the globe in ecosystems from deserts to mountains and marshes to grasslands.

In an unchanged world, "wetlands would build vertically at faster rates," says Kirwan, "or move inland to higher elevations."

The paper's co-author is Patrick Megonigal of the Smithsonian Environmental Research Center.

A wetland is land that's saturated with water, whether permanently or seasonally. The water found in wetlands can be saltwater, freshwater or brackish water. Main wetland types include swamps, marshes, bogs and fens.

Wetlands have developed several ways to build elevation to keep from drowning.

Aboveground, tidal flooding provides one of the biggest assists. When marshes flood during high tides, sediment settles out of the water, adding new soil. As sea level rises and flooding occurs more often, marshes react by building soil faster.

Belowground, the growth and decay of plant roots add organic matter.

Even erosion can work in wetlands' favor, as sediment lost at one marsh may be deposited in another. While a particular wetland may lose ground, the total wetland area may remain unchanged.

But, if a wetland becomes so submerged that its vegetation dies off, these "positive feedback loops" are lost. Similarly, if sediment delivery to a wetland is cut off, that wetland can no longer build soil to outpace rising seas.

"This study reveals the complex, long-term interplay among processes that maintain coastal wetlands in the face of sea level rise," says Saran Twombly, program director in NSF's Division of Environmental Biology, which funds the NSF Virginia Coast Reserve LTER site.

"Humans are newcomers to this delicate balance. The future of a habitat so essential to human well-being depends on how severely we alter it."

For example, groundwater withdrawal and artificial drainage can cause the land to sink, as is happening in Chesapeake Bay.

Because of this subsidence, eight of the world's 20 largest coastal cities have relative sea level rise greater than climate change projections.

Dams and reservoirs also prevent 20 percent of the global sediment load from reaching the coast.

Marshes on the Yangtze River Delta, for example, have survived a relative sea level rise of more than 50 millimeters per year since the 7th century--until the recent building of more than 50,000 dams cut off the supply of sediment and accelerated erosion.

"Tidal marshes are amazing ecosystem engineers that can raise themselves upward if they remain healthy, especially if there is sediment in the water," says Megonigal.

"We know there are limits, however. Those limits are changing as people alter the environment."

-NSF-

Media Contacts Cheryl Dybas, NSF (703) 292-7734 cdybas@nsf.gov
Dave Malmquist, Virginia Institute of Marine Science (804) 684-7011 davem@vims.edu
Kristen Minogue, Smithsonian Environmental Research Center (443) 482-2325 minoguek@si.edu

Related WebsitesNSF Long-Term Ecological Research Network:

http://www.lternet.edu
NSF Virginia Coast Reserve LTER Site:

http://www.lternet.edu/sites/vcr
NSF Publication: Discoveries in Long-Term Ecological Research:

http://www.nsf.gov/pubs/2013/nsf13083/nsf13083.pdf?WT.mc_id=USNSF_25&WT.mc_ev=click

The National Science Foundation (NSF) is an independent federal agency that supports fundamental research and education across all fields of science and engineering. In fiscal year (FY) 2012, its budget was $7.0 billion. NSF funds reach all 50 states through grants to nearly 2,000 colleges, universities and other institutions. Each year, NSF receives about 50,000 competitive requests for funding, and makes about 11,500 new funding awards. NSF also awards about $593 million in professional and service contracts yearly.