Coastal Creatures May Have Reduced Ability to Fight Off Infections in Acidified Oceans

The ocean is filled with a soup of bacteria and viruses. The animals living in these environments are constantly under assault by pathogens and need to be able to mount an immune response to protect themselves from infection, especially if they have an injury or wound that is openly exposed to the water.

Louis Burnett, professor of biology and director of the Grice Marine Laboratory of the College of Charleston, and Karen Burnett, research associate professor at Grice Marine Laboratory of the College of Charleston, study the effects of low oxygen and high carbon dioxide on organisms’ immune systems. They have found that organisms in these conditions can’t fight off infections as well as animals living in oxygen rich, low carbon dioxide environments.

The Burnetts will be presenting their findings at the Global Change and Global Science: Comparative Physiology in a Changing World conference from August 4-7, 2010 in Westminster, Colorado. This conference is in part sponsored by the American Physiological Society (http://www.the-aps.org). The full conference program can be found at http://www.the-aps.org/meetings/aps/comparative/preprogram.htm.

Decreased Ability to Fight Infection
The researchers examined fish, oysters, crabs and shrimp, and showed that all these animals have a decreased ability to fight off infection of Vibrio bacteria when subjected to low oxygen, high carbon dioxide conditions. It takes about half as much bacteria to administer a lethal dose to a creature in a low oxygen, high carbon dioxide environment.

“Our approach is exciting because traditionally physiologists haven’t considered bacteria or disease as a natural environmental barrier, so it’s a pretty open field,” says Louis Burnett.

Apparently, if marine animals are challenged with a pathogen, a large number of their blood cells disappear within a few minutes. The blood cells clump up to attack the pathogen, but also lodge in the gills (the sea critter version of lungs), where the body gets it oxygen. The scientists see evidence that sea animals fighting off infection lower their metabolism, which slows down other important processes like making new proteins.

“Everything we see points to the fact that if an animal that mounts a successful immune response then their gill function and ability to exchange oxygen is reduced by about 40 percent, which is why they seem to be having such problems living in low oxygen conditions,” says Karen Burnett. “If you add high carbon dioxide to that, it gets worse.”

The researchers are now using microarrays to measure changes in gene expression in marine organisms that are exposed to bacteria under low oxygen, high carbon dioxide conditions.

“After exposure to these conditions for only a day, animals at the molecular level have given up in trying to adapt to the situation, and they are going into molecular pathways that indicate cell death,” says Karen Burnett.

The coastal animals the Burnett’s study live in environments where natural levels of oxygen and carbon dioxide fluctuate. Theoretically, these animals are already adapted for varied environments, and yet they still struggle with these changing conditions. It’s alarming that deep-water animals may be much more affected by ocean acidification, since they are not used to the ebb and flow of oxygen and carbon dioxide levels.

“Some of the models for how the coastal organisms adapt may help researchers predict how deep water organisms are going to be affected by overall climate change too,” says Louis Burnett.

NOTE TO EDITORS: Dr. Burnett will discuss his findings at the conference Global Change and Global Science: Comparative Physiology in a Changing World, sponsored by the American Physiological Society (APS; www.the-aps.org) To arrange an interview with Dr. Burnett, please contact Donna Krupa at 301.634.7209 or dkrupa@the-aps.org. To see the full conference program log on to http://www.the-aps.org/meetings/aps/comparative/preprogram.htm.

Physiology is the study of how molecules, cells, tissues and organs function to create health or disease. The American Physiological Society (www.The-APS.org/press) has been an integral part of this discovery process since it was established in 1887.