Who needs Chesapeake crabs?

Our Oceans, where life started Are Now Dying!

What is killing them? Among major causes Pollution from

• Tourism
• Coastal Developments
• Industrial agriculture
• Intensive farming
• Coal-burning power plants
• Shipping
• Dumping

Causing

• Eutrophication and Hypoxia
• Desertification
• Acidification
• Dead Zones

Our Dead Zone Largest Ever This Year!

Ocean “deserts” are expanding much faster than predicted, it is believed that the ocean “desertification” may result in the population decline of many fish species.

Black areas in the Atlantic and Pacific Oceans are the least productive. (Credit NOAA)

Development takes toll on Chesapeake crabs

Wed Mar 4, 2009
By Andy Sullivan

REEDVILLE, Virginia (Reuters) – It doesn’t look like a disaster area.

Crab boats dart back and forth on this inlet of the Chesapeake Bay as they have for generations. On the shore, million-dollar vacation homes catch the morning sun.

But watermen aren’t pulling blue crabs out of the Bay this winter. After years of decline, the U.S. Commerce Department declared the fishery a federal disaster last September and Maryland and Virginia shut it down until spring.

It was a symbolic as well as an economic blow for the men who harvest the region’s defining culinary treat.

Watermen faced a stark choice: Stay ashore until March, or take a state job pulling abandoned crab traps and other junk from the bottom of the Bay.

So on this frigid winter morning, Spencer Headley is on cleanup duty, a floating janitor on one of the country’s most intractably polluted bodies of water.

It’s decent money — $300 a day plus expenses — and you can’t beat those government hours. But Headley, 32, wonders why he must now rely on the state rather than the water for his livelihood.

“We’re not trying to tear the Bay up. We’re just trying to make a living off a fishery that’s been going for more than 100 years,” he says, one eye on his sonar display.

“Why all of a sudden is it a disaster?”

The Susquehanna River, which enters the Chesapeake Bay at its northern end, carries 40 percent of the nitrogen that flows into the Bay—the largest single source. There is so much nitrogen in the northern Bay that algae have all the “fertilizer” they need, and changes in streamflow do little or nothing to affect the growth of algal blooms. This satellite image shows brown water flowing from the Susquehanna. (NASA image by Robert Simmon, based on Landsat-7 data provided by the UMD Global Land Cover Facility. Caption: Earth Observatory).

STEADY STREAM OF POLLUTANTS

That disaster has been steadily building since Europeans first mapped the Bay’s shores 400 years ago.

Stretching roughly 200 miles from northern Maryland to southern Virginia, the Chesapeake is the largest estuary in the United States and for hundreds of years was one of its most productive fisheries, yielding shad, sturgeon, oysters and baitfish. As recently as 1993, the Bay accounted for about half of the country’s blue crab harvest.

But the fishery has declined as the region has boomed. Roughly 16.6 million people live in its watershed, which stretches as far as upstate New York, and an average of 439 more move to the region each day. That means more houses and more traffic as urban sprawl eats up forests and farmland.

The impact of this growth can be seen along Sligo Creek, which draws herons and foxes to its banks as it winds through the densely packed suburbs northeast of Washington, D.C.

Along the way, the creek picks up a steady stream of pollutants: lawn fertilizer, pet feces, motor oil and silt, washing off the parking lots and other hard surfaces that cover 35 percent of its 12-square-mile watershed.

Local activist Bruce Sidwell points out a sewer line that runs across the creek, exposed by years of erosion. It could be leaking raw sewage before long.

Sidwell’s grass-roots group reports polluters and organizes litter pickups, and he’s eager to showcase the filtering pools that help clean the creek’s upper reaches.

But water quality remains poor and is not likely to improve without substantial changes in the landscape, Sidwell says.

“It would take quite an effort to get it up to ‘fair’ water quality,” he says.

On its journey to the Chesapeake, water from Sligo Creek mingles with runoff from farms and sewage treatment plans.

Nitrogen and phosphorus in that runoff feed massive algae blooms that suck oxygen out of the water each summer, killing clams and worms that provide the blue crab with food and aquatic grasses that give it shelter.

Last year, the “dead zone” covered 40 percent of the Bay.

Not surprisingly, crabs have suffered. The 2007 catch was the worst in recorded history, and last year the catch was even worse in Virginia and only slightly better in Maryland.

With fewer crabs in the Bay, watermen now routinely catch far more than the 46 percent that scientists say is the upper limit to maintain a healthy population.

Observers say time is running out to reverse the damage.

“The Bay is now degraded to the point that its basic ability to withstand even low levels of pollution is in jeopardy,” said Naval Academy professor Howard Ernst, an expert on the restoration effort.

A 25-year, $6 billion cleanup effort by state governments and the U.S. Environmental Protection Agency has come under widespread criticism as it has repeatedly fallen short of its stated goals. Officials also overstated their success to keep funding in place.

The Chesapeake Bay Foundation, an environmental group, sued the EPA last month to force it to set a firm cap on pollutants. The group is heartened that new EPA Administrator Lisa Jackson has promised to make the Bay cleanup a priority.

“We certainly are hearing the right words,” said foundation president Will Baker. “But to be honest, we have heard those words for 30, 35 years and what we need to see is action.”

‘GRASS THAT’S PAINTED ON’

Headley has seen the changes up close. He’s pulled up traps filled with dead crabs, suffocated in oxygen-depleted water. He’s seen the state reduce the number of traps he’s allowed to drop in the water from 500 to 350.

And he’s seen mansions sprout along the shoreline, their lawns fertilized with the very chemicals that are choking the Bay. “Grass as green as you’ve ever seen in your life, looks like it’s painted on,” he says.

Easing his 46-foot (14 meter) Chesapeake Bay Deadrise back to the dock, Headley passes rusted shacks and crumbling chimneys, the ruins of once-thriving oyster and baitfish industries.

The crab fishery, too, is a shadow of its former self, employing 40 percent fewer jobs than it did a decade ago.

There are only a handful of crabbers working out of Reedville now, Headley says, but plenty of people are moving to town to enjoy the scenery.

Headley knows everybody on the water, but sometimes when he comes ashore he doesn’t recognize a soul. A way of life is dying. (Editing by Alan Elsner). Copyright the author or news agency. URL: http://www.reuters.com/article/environmentNews/idUSTRE52302020090304

Related Links:

• Our Oceans
• The Eight Steps that Help Kill More of Our Fish
• Oceans, Where Life Started, Are Dying – Part III
• Our Dead Zone Largest Ever This Year!

Oceans, Where Life Started, Are Dying – Part II

WILD FACTS SERIES – Lethal Marine Pollution

Major Problems: Fertilizer Runoff; Tourism; Coastal Developments; Marine Transportation; and Ocean Warming due to climate change

Pollution Load

About 80% of the pollution load in the oceans originates from land-based activities directly affecting up to 80 percent of the world’s coastal areas and threatening the well-being of up to 4.5 billion people who live within a 60km radius of the coast, according to the UNEP (about 2billion people live in coastal urban centers).

Of the world’s 23 mega-cities (those with over 2.5 million inhabitants),
16 are in the coastal belt and are growing at a rate of about one million
people per day. ~ UN (Image credit: NOAA)

The sources of water pollution include

• Municipal and industrial wastes
• Agricultural runoff
• Atmospheric deposition

Creeping Dead Zone (Pub. Domain. Credit NASA)

Creeping Dead Zones

The hypoxic (low-oxygen) areas in the oceans are called dead zones. The 200 or so oxygen depleted regions in our oceans are normally caused by nutrients from runoff (chemical fertilizer, manure, sewage…). The increase in nutrients like nitrogen and phosphorous in the water is called eutrophication, a process that promotes excessive growth and decay of weedy plants and that is likely to cause severe reductions in water quality. When the decaying organic matter produced by aquatic vegetation or phytoplankton (an algal bloom) sinks to the bottom it undergoes breakdown by bacteria (bacterial respiration), a process which consumes the dissolved oxygen in the water and produces carbon dioxide. Respiration kills zooplankton, fish, crabs, clams, shrimp, and all other species that swim in the water or dwell on the muddy bottom of the lakes, rivers, estuaries and other water bodies. The water becomes cloudy and turns to a shade of red, yellow, green, or brown.

The size of aquatic and marine dead zones varies from about 1 to 70,000 square kilometers.

A dense bloom of poisonous cyanobacteria in the Potomac River estuary
(Credit:NOAA)

Gulf of Mexico

The largest dead zone in the US coastal waters measures about 25,000 square kilometer in the Gulf of Mexico caused by high-nutrient runoff dumped by the Mississippi River whose vast drainage basin covers the Midwest, the center of U.S. agribusiness. Another dead zone off the coast of Texas was discovered in July 2007.

According to a USGS study most of nutrients (75 percent of nitrogen and phosphorus) come from just nine states (total of 31 states share the basin) in the Mississippi River Basin: Arkansas, Illinois, Indiana, Iowa, Kentucky, Mississippi, Missouri, Ohio, Tennessee. Some 12 percent of the pollution originates from urban sources.

• Corn and soybean cultivation is responsible for the largest share of nitrogen runoff to the Gulf.
• Animal manure (see also New Zealand and Australia) on pasture and rangelands contribute a total of 37 percent to phosphors pollution.
• Crop cultivation is responsible for a total of 43 percent of phosphorus runoff.

Low oxygen levels in the waters of the Gulf Coast have affected the fish reproductive system causing “decreased size of reproductive organs, low egg counts and lack of spawning.” The nation’s largest and most productive fisheries are threatened as the result.

The Following excerpts are from Wikipedia: In a study of the Gulf killifish by the Southeastern Louisiana University done in three bays along the Gulf Coast, fish living in bays where the oxygen levels in the water dropped to 1 to 2 parts per million (ppm) for 3 or more hours per day were found to have smaller reproductive organs. The male gonads were 34% to 50% as large as males of similar size in bays where the oxygen levels were normal (6 to 8 ppm). Females were found to have ovaries that were half as large as those in normal oxygen levels. The number of eggs in females living in hypoxic waters were only one-seventh the number of eggs in fish living in normal oxygen levels. (Landry, et al., 2004)

Another study by the University of Texas at Austin Marine Science Institute was done on the Atlantic croaker fish in Pensacola Bay, Florida. The study was of year-old croakers that live in an estuary that has summer-long hypoxic conditions. During the study, none of the fish spawned at the expected time, or later. Examination of sample fish determined that they lacked mature eggs or sperm. (Murphy, et al., 2004)

Fish raised in laboratory created hypoxic conditions showed extremely low sex-hormone concentrations and increased elevation of activity in two genes triggered by the hypoxia-inductile factor (HIF) protein. Under hypoxic conditions, HIF pairs with another protein, ARNT. The two then bind to DNA in cells, activating genes in those cells.

Under normal oxygen conditions, ARNT combines with estrogen to activate genes. Hypoxic cells in a test tube didn’t react to estrogen placed in the tube. HIF appears to render ARNT unavailable to interact with estrogen, providing a mechanism by which hypoxic conditions alter reproduction in fish. (Johanning, et. al, 2004)

It might be expected that fish would flee this potential suffocation, but they are often quickly rendered unconscious and doomed. Slow moving bottom-dwelling creatures like clams, lobsters and oysters are unable to escape. All colonial animals are extinguished. The normal mineralization and recycling that occurs among benthic life-forms is stifled.

According to USGS Associate Director for Water, Dr. Robert Hirsch, the number of water quality monitoring stations along the Mississippi River Basin region has been decimated from 425 stations 15 years ago to just 32.

A combined sewer overflow runoff entering Fall Creek in Indianapolis, Indiana
(photo credit: Charles Crawford; courtesy USGS).

Agrofuel [biofuel] Crop Impact in The Gulf of Mexico

According to a computer model designed by researchers at the University of Wisconsin-Madison and the University of British Columbia, the exponentially increasing amounts of fertilizer needed to meet US production goals for biofuel production, especially the corn-ethanol, would increase the nitrogen loading from the Mississippi River into the Gulf of Mexico by up to 19 percent, increasing the size of dead zones.

The Mississippi River is about 2,300 miles (3,705 kilometers) long, according to the US Geologic survey. The River Basin or Watershed drains 41% of land in United States, an area of about 1.8 million square miles. Thirty-one states and two Canadian provinces are included in the watershed. The Mississippi carries an average of 500,000 tons of sediment each day.

The US Pacific Coast

Dead zone in the US Pacific coast covers an area of about 3,000 square kilometers. Worsened by strong winds caused by climate change, the Pacific dead zone has reoccurred every summer since 2002. See Photos of research during hypoxic events off the Oregon Coast

ROW

Other countries and regions where other dead zones have been reported since the 1970s include

• Chesapeake Bay (US)
• strait called the Kattegat strait (Scandinavia)
• The Baltic Sea (in multiple fishing grounds)
• Northern Adriatic
• And coastal waters of
• South America
• China
• Japan
• Throughout Southeast Australia
• New Zealand (Both Australia and NZ are major sources of industrial agriculture as well as sheep and cattle factory farming)

A map of the world’s dead zones created by Dr. Robert Diaz of the Virginia Institute of Marine Science (VIMS). Diaz estimates that the number of dead zones will double within a decade. Source: NASA

Coming Soon:
Oil Pollution

References:

• Landry, C.A., S. Manning, and A.O. Cheek. 2004. Hypoxia suppresses reproduction in Gulf killifish, Fundulus grandis. e.hormone 2004 conference. Oct. 27-30. New Orleans.
• Murphy, C. . . . P. Thomas, et al. 2004. Modeling the effects of multiple anthropogenic and environmental stressors on Atlantic croaker populations using nested simulation models and laboratory data. Fourth SETAC World Congress, 25th Annual Meeting in North America. Nov. 14-18. Portland, Ore.
• Johanning, K., et al. 2004. Assessment of molecular interaction between low oxygen and estrogen in fish cell culture. Fourth SETAC World Congress, 25th Annual Meeting in North America. Nov. 14-18. Portland, Ore.
• Nutrients in the Nation’s Waters–Too Much of a Good Thing? U.S. Geological Survey Circular 1136.

Related Links:

• Pisco
• Living on Earth
• PLASTIC POLLUTION IN THE MARINE ENVIRONMENT:BOATERS CAN HELP CONTROL A GROWING PROBLEM
• Plastic in the Sea
• Trashed: Across the Pacific Ocean, Plastics, Plastics, Everywhere
• The Deadliest Predator in the Sea
• Plastic Oceans: unimaginable pollution
• Plastic pollution in our oceans (slideshow)
• Oceans
• Pollution of the Ocean by Plastic and Trash
• Pacific’s plastic pollution threatens our food chain
• Plastic Pellets in the Aquatic Environment: Sources and Recommendations
• A Primeval Tide of Toxins
• Social Responses (PDF)
• UN Atlas of Oceans
• Dead Zones

• North Pacific Gyre (Links to videos)

See Also:  Our Dying Oceans (Parts I, II,III, and IV)

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