livescience.com Yahoo News 5 May 10;
Bacteria and other germs latch on to clumps of decaying matter floating in the ocean, creating "germ islands" that could spread disease, a new study reveals.
When plants and animals near the surface of the ocean die, they decay and gradually fall to the seafloor. This dead matter can clump together with sand, soot, fecal matter and other material to form what is called "marine snow," so named because it looks like tiny bits of white fluff. Marine snow continuously rains down on the deep ocean, feeding many of the creatures that dwell there.
A group of scientists studying marine snow found that these clumps, or aggregates, may act as island-like refuges for pathogens, the general term for disease-causing organisms or germs, such as bacteria and viruses. (The "island" term comes from the comparison of the existence of pathogens on marine snow with the way insects, amphibians and other creatures establish homes and persist on remote islands in the oceans.)
The scientists are evaluating the degree to which aggregates made up of this decaying organic matter provide a favorable microclimate for aquatic pathogens. These "refuges" seem to protect pathogens from stressors, such as sunlight and salinity (amount of salt in the water) changes, and from predators. They also might provide sources of nourishment for the pathogens.
"If the microclimate is favorable, aggregates likely facilitate the persistence, prevalence and dispersal of aquatic pathogens," said study team member Fred Dobbs of Old Dominion University (ODU) in Norfolk, Va.
The researchers found the bacteria had an increased metabolism (meaning they were more active), and a greater diversity, when living on individual organic aggregates compared with those in the surrounding water. These results indicate that aggregates might be potential reservoirs and vectors for aquatic pathogens.
"We've shown, for example, that vibrios [a type of pathogen] proliferate in aggregates and decline in adjacent, aggregate-free water," the authors wrote in the paper describing their findings, which is included in the May 4 issue of the journal Aquatic Microbial Ecology.
Current models developed to look at the transmission of waterborne diseases and illnesses, however, don't consider the benefits microorganisms gain from hitching a ride on marine snow.
This detritus may skew water-sampling procedures and mathematical models used to predict the transmission of waterborne diseases to humans. When water sampling is conducted - to determine whether recreational waters should be open to swimmers, or whether shellfish beds should be closed to fishers - aggregates lend a hit-or-miss aspect to the testing.
A sample might include only water without aggregates, giving false-negative results that no danger exists.
"The presence or absence of a single aggregate in an environmental water sample could drastically alter the measure of bacterial concentrations," Dobbs said.
The scientists are using the information they have gathered to help predict "how long bacteria can thrive on an individual aggregate and the relationship between the size of the aggregate and the diversity of species found on it," said lead author of the study Maille Lyons, also of ODU.
A better understanding of these relationships could help make water-sample tests more accurate.
The research was funded by a National Science Foundation (NSF)-National Institutes of Health (NIH) Ecology of Infectious Diseases (EID) grant.
Islands of Germs: Researchers Discover Pathogens Floating on Tiny Clumps of Aquatic Detritus
ScienceDaily 5 May 10;
Researchers have found evidence that "marine snow"--aggregates of organic material floating in water bodies--may act as microscopic, island-like refuges for pathogens, or disease-causing organisms. This detritus may skew water sampling procedures and mathematical models used to predict the transmission of waterborne diseases to humans.
The scientists responsible for these findings, funded by a National Science Foundation (NSF)-National Institutes of Health (NIH) Ecology of Infectious Diseases (EID) grant, published their results in the journal Aquatic Microbial Ecology.
The findings are the first to compare the existence of pathogens on marine snow with the way insects, amphibians and other creatures establish homes and persist on remote islands in the oceans.
Theories in island biogeography--the study of the factors that affect species richness on islands--also apply to microscopic drifting aggregates, according to Maille Lyons, a scientist at Old Dominion University (ODU) and lead author of the paper, with ODU co-authors Fred Dobbs and Holly Gaff. Other authors are J. Evan Ward of the University of Connecticut; Randall Hicks of the University of Minnesota, Duluth; and John Drake of the University of Georgia.
"These predictions help explain whether and for how long bacteria can thrive on an individual aggregate," said Lyons, "and the relationship between the size of the aggregate and the diversity of species found on it."
"This study shows that theory developed for the 'macroscopic' world applies equally to the microscopic one," said Sam Scheiner, program director in NSF's Division of Environmental Biology, which co-funds the EID program with NSF's Directorate for Geosciences.
"It allows scientists to link the small to the large," said Scheiner, "and to provide predictive tools for understanding disease transmission."
Aggregates are made up of small bits of detritus and other components--some of which are living organisms--that usually aren't visible to the naked eye. When these tiny components come in contact with each other, they clump together.
The scientists are evaluating the degree to which detritus-based organic aggregates provide a favorable microclimate for aquatic pathogens.
These "refuges" seem to protect pathogens from stressors such as sunlight and salinity changes, and from predators. They also may provide sources of nourishment for the pathogens.
"If the microclimate is favorable, aggregates likely facilitate the persistence, prevalence and dispersal of aquatic pathogens," said Dobbs.
The researchers found an increased metabolic response, and diversity of bacteria, on individual organic aggregates compared to the surrounding water, indicating that aggregates may be potential reservoirs and vectors for aquatic pathogens.
Current models of the transmission of waterborne diseases and illnesses, however, don't consider the benefits microorganisms gain from hitching a ride on marine snow.
"We've shown, for example, that vibrios [a type of pathogen] proliferate in aggregates and decline in adjacent, aggregate-free water," the journal paper states.
When water sampling is conducted--to determine whether recreational waters should be open to swimmers, or whether shellfish beds should be closed to fishers--aggregates lend a hit-or-miss aspect to the testing.
A sample might include only water without aggregates, giving false-negative results that no danger exists.
"The presence or absence of a single aggregate in an environmental water sample," said Dobbs, "could drastically alter the measure of bacterial concentrations."