West Coast Toxic Algae Bloom Probably Largest Ever

Dangerous levels of potent neurotoxin domoic acid found along the West Coast

Federal scientists set out from Oregon Monday to study the massive bloom, which could be the largest ever discovered off the US West Coast, said a report.

“The effects stretch from Central California to British Columbia, and possibly as far north as Alaska. Dangerous levels of the natural toxin domoic acid have shut down recreational and commercial shellfish harvests in Washington, Oregon and California this spring.”

“Extremely high” levels of neurotoxin domoic acid found in Monterey Bay

Extremely high concentrations of the potent toxin domoic acid were detected in Monterey Bay by monitors led by UC Santa Cruz in May, and more blooms were reported elsewhere along the U.S. west coast.

“It’s a pretty massive bloom. The domoic acid levels are extremely high right now in Monterey Bay, and the event is occurring as far north as Washington state. So it appears this will be one of the most toxic and spatially largest events we’ve had in at least a decade,” said Kudela, professor of ocean sciences and at UC Santa Cruz.

Domoic acid is a potent neurotoxin produced by tiny algae called Pseudo-nitzschia (a type of diatom). The toxin was first detected in early May, and within the month researchers had detected the highest concentrations of domoic acid ever observed in Monterey Bay, off the coast of California.

“We have confirmed domoic acid at very high levels in mussels and anchovy,” Kudela said. His lab also found very high levels of the toxin in samples from a dead pelican found on the beach in Moss Landing, and testing of sea lion samples is under way. “Domoic acid has clearly worked its way into the food web,” he said.

The acid has claimed several lives and sickened scores of others, the Washington Department of Fish and Wildlife reported.

Paralytic shellfish poisoning (PSP) and diarrhetic shellfish poisoning (DSP)

Meantime, researchers have discovered two other types of toxins, said to be a rare combination, in shellfish in Puget Sound and along the Washington coast, said Vera Trainer, a senior scientist at the Northwest Fisheries Science Center in Seattle.

Read more…

 

Terrible Ocean Headlines

Even the average high school grad could have made an educated guess …

About one third of the world’s annual emissions of CO2 is absorbed by the surface of the oceans forming carbonic acid (ancient name acid of air or aerial acid), H₂CO_3, which is increasing the acidity of the oceans to as much as 7.7 pH in some areas off the California coast. [Pre-industrial (1700s) ocean pH: 8.179]

Ocean Acidity Kills Corals. Photo Credit: Associated Press. Image may be subject to copyright!

“We were completely surprised because people had been looking at the effect of acidification on calcified structures of marine animals, but there was no evidence to suggest it was affecting non-calcified structures, like a sperm or an egg,” lead-scientist Jane Williamson from Macquarie University told Reuters on Friday.

“It is widely believed that seawater is chemically well-buffered, but these results show that the acidification process already well underway may threaten the viability of many marine species,” Williamson said.

The sea urchins study found a link between increased ocean acidity and a reduction in fertility (Credit: ABC News). Image may be subject to copyright!

“What we have now is evidence that the world’s marine life is far more sensitive to ocean acidification than first suspected, and that means our oceans may be very different places in the not-too-distant future.”

Related Links:

• World Oceans in Extreme Danger
• Southern Ocean already losing ability to absorb CO₂
• The Ocean’s Carbon Balance
• Oceans, Where Life Started, Are Dying – Part IV

Up to 410 dead zones with a combined area of about 250,000km² and counting!

Summertime satellite observations of ocean color from MODIS/Aqua show highly turbid waters which may include large blooms of phytoplankton extending from the mouth of the Mississippi River all the way to the Texas coast. When these blooms die and sink to the bottom, bacterial decomposition strips oxygen from the surrounding water, creating an environment very difficult for marine life to survive in. Reds and oranges represent high concentrations of phytoplankton and river sediment. Image taken by NASA and provided courtesy of the NASA Mississippi Dead Zone web site.

No of Dead Zones

• 1970: 40 dead zones
• 1980: 65
• 1990: 135
• 2000: 305
• 2008: 410 dead zones with a combined area of about 250,000km²

“The biggest one measures about 30,000 square miles in the Baltic Sea, the researchers said. This is followed in size by one in the Gulf of Mexico starting at the mouth of the Mississippi River in the United States and one at the mouth of China’s Yangtze River in the East China Sea.” Reuters reported.

“It’s not sort of a local or regional problem, which is how it was thought of in the past,” said Robert Diaz of the College of William and Mary’s Virginia Institute of Marine Science. “It is actually a global problem.”

“Most of it is agricultural-based, but there is a lot of industrial nitrogen in there, too, if you consider electric generation industrial,” added Diaz.

Related Links:

• Eutrophication and Hypoxia
• Congratulations! We Are Breaking Another Record: Our Dead Zone in Gulf of Mexico
• Dead Zones
• Our Oceans [Index Page]
• The Eight Steps that Help Kill More of Our Fish
• Marsification of Earth

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Oceans, Where Life Started, Are Dying – Part IV

Wild Facts Series: Just when you thought the oceans were dying painlessly!

Carbon Emissions Make Oceans Corrosive!

‘Acidified’ Water Threatens Marine Life on the Continental Shelf from Canada to Mexico: NOAA

Researchers found evidence of corrosive water about 20 miles off the west coast of North America from Canada to Mexico last summer. The ocean water on the western North American continental shelf was previously thought not to be “acidified.”

“Ocean acidification” is caused by the ocean’s absorption of carbon dioxide (CO2) from the atmosphere, a process which makes water corrosive.

Effects of increasing carbon dioxide and temperature on coral reefs. (NOAA Coral Reef Watch)

“Acidification of the Earth’s ocean water could have far-reaching impacts on the health of our near-shore environment, and on the sustainability of ecosystems that support human populations through nourishment and jobs,” said Richard W. Spinrad, NOAA assistant administrator for oceanic and atmospheric research. “This research is vital to understanding the processes within the ocean, as well as the consequences of a carbon-rich atmosphere.”

“Our findings represent the first evidence that a large section of the North American continental shelf is seasonally impacted by ocean acidification,” said Feely. “This means that ocean acidification may be seriously impacting marine life on our continental shelf right now.”

“While this absorption provides a great service to humans by significantly reducing the amount of greenhouse gases in the atmosphere and decreasing the effects of global warming, the change in the ocean chemistry affects marine life, particularly organisms with calcium carbonate shells, such as corals, mussels, mollusks, and small creatures in the early stages of the food chain,” said Feely.

NOAA said: “Previous studies found ocean acidification at deeper depths farther from shore. The researchers said that the movement of the corrosive water appears to happen during the upwhelling season during the spring and summer, when winds bring CO2 -rich water up from depths of about 400-600 feet onto the continental shelf. The water that upwells off of the North American Pacific coast has been away from the surface for about 50 years.

Typical coral-reef community observed in the U.S. Virgin Islands. [Species lables: the image to view labels: Ma, boulder star coral (Montastrea annularis); Dc, knobby brain coral (Diploria clivosa); Pa, mustard hill coral (Porites astreoides); Pp, finger coral (Porites porites); D, dead coral (probably Porites astreoides); O, octocoral (soft coral); S, sponge.] Photograph by Nathan Smiley, USGS.

“The field study collected samples from Queen Charlotte Sound, Canada, to San Gregorio Baja California Sur, Mexico. The closest they found corrosive water was about four miles off of the northern California coast.”

“We did not expect to see this extent of ocean acidification until the middle to the end of the century,” said Sabine. “Because of this effort, we have a baseline for future observations as we continue to study and monitor the relationship of biological and physical processes and their ability to respond to ocean acidification.”

“We did not expect to see this extent of ocean acidification until the middle to the end of the century,” said Sabine. “Because of this effort, we have a baseline for future observations as we continue to study and monitor the relationship of biological and physical processes and their ability to respond to ocean acidification.”

“When the upwelled water was last at the surface, it was exposed to an atmosphere with much less CO2 than today and future upwelled waters will probably be more acidic than today’s because of increasing atmospheric CO2,” said Hales, a professor of chemical oceanography, who is also funded by NASA.

“We don’t know how this will affect species living in the zone below the level of the lowest tides, out to the edge of the continental shelf,” said Ianson, an oceanographer. “We do know that organisms like corals or pteropods are affected by water saturated with CO2. The impacts on other species, such as shellfish and other juvenile fish that have economic significance, are not yet fully understood.”

“In Baja California, we have several Mediterranean-climate coastal lagoons where the main external physical and biogeochemical forcing is from the neighboring coastal ocean, strongly influenced by upwelling,” said Hernandez-Ayon, a coastal oceanographer. “We are concerned about these areas because they play an important role as nurseries and feeding grounds of juvenile fish populations but are also are ideal sites for shellfish aquaculture.” More …

What is Bleaching?

Corals are very sensitive to temperature change: a 1–2º C change in local temperature above their normal summer maximum can lead to a phenomenon called ‘bleaching’, whereby the corals expel their vital algal symbionts (algae which live in the cells of the coral), leaving the coral tissues translucent.

Bleached Coral (Pocillopora) NOAA’s Pacific Islands Fisheries Science Center of the National Marine Fisheries Service.

In 1998, a single bleaching event led to the loss of almost 20% of the world’s living coral. Corals can recover from these events but repeated episodes are likely to weaken the coral ecosystem, making them more susceptible to disease and causing a loss of biodiversity. (Source)

How will ocean acidification affect marine life?

Corals, calcareous phytoplankton, mussels, snails, sea urchins and other marine organisms use calcium (Ca) and carbonate (CO3) in seawater to construct their calcium carbonate (CaCO3) shells or skeletons. As the pH decreases, carbonate becomes less available, which makes it more difficult for organisms to secrete CaCO3 to form their skeletal material. For animals in general, including invertebrates and some fish, CO2 accumulation and lowered pH may result in acidosis, or a build up of carbonic acid in the organism’s body fluids. This can lead to lowered immune response, metabolic depression, behavioral depression affecting physical activity and reproduction, and asphyxiation. Since the oceans have never experienced such a rapid acidification, it is not clear if ecosystems have the ability to adapt to these changes (1,2). Effects of ocean acidification on organisms and ecosystems are still poorly understood. Over the last few years, research has intensified significantly to fill the many knowledge gaps. (Source)

Related Links:

• International Scientists Find ‘Acidified’ Water on the Continental Shelf from Canada to Mexico
• How will ocean acidification affect marine life ?
• Ocean Acidification
• Integrated Coral Observing Network

• The Eight Steps that Help Kill More of Our Fish
• Global warming could starve oceans of oxygen: study
• The Floating Toxic Garbage Island
  
• Oceans, Where Life Started, Are Dying – Part III
• Oceans, Where Life Started, Are Dying – Part II
• Oceans, Where Life Started, Are Dying – Part I