May 6, 2014
The recent appearance of the freshwater algae known as “rock snot” on river bottoms worldwide is caused by a native species responding to changing environmental conditions rather than by accidental introductions by fishermen or the emergence of a new genetic strain as widely believed, a Dartmouth College-led study suggests.
In fact, the algae have been native to much of the world for thousands of years, but conditions promoting visible growths were absent or rare. The study, which includes researchers from Dartmouth and Environment Canada, appears in the journal BioScience. A PDF of the study, photos and a video clip are available on request.
Didymosphenia geminata, also known in the scientific vernacular as “didymo,” is especially worrisome in salmon and trout rivers because it affects the insects they eat. The study suggests multimillion-dollar eradication efforts with chemicals and fishing restrictions are misguided, and that resources should be redirected at understanding and mitigating the environmental factors that trigger the blooms.
“Correctly identifying an invasive species as either native or nonnative is important for developing sound policy, management and scientific research programs because effective responses depend on knowing whether the species’ dominance is caused by ecological or evolutionary novelty, changes in environmental conditions that facilitate it, or both,” said Professor Brad Taylor, the study’s lead author.
Didymo blooms were hastily attributed to human introductions or the emergence of new genetic strain because the absence of evidence was used as evidence of absence in many locations. “Even in locations where rock snot had been recorded a century ago, this information was either ignored or the idea of a new genetic strain was adopted,” Taylor says.
Algal blooms are often caused by excessive phosphorus and other nutrient inputs, but didymo blooms occur because phosphorus is low. Rock snot lives on river bottoms and obtains nutrients from the water above. When nutrients are rare, the algae produce long stalks that extend the cell into the water above to access nutrients. The result of this stalk growth is thick mats covering the river bottom. “The paradox of didymo blooms in low-nutrient rivers is not really a paradox at all. However, the idea that low phosphorus can cause an algal bloom is hard for people to accept because we are all taught that more nutrients equal more algae,” Taylor says. The study explains that other algae and bacteria respond similarly to low nutrients, but rock snot blooms are unprecedented, making this organism a good sentinel of what could be the new norm in many pristine rivers worldwide.
The new research suggests rock snot blooms have become more common because of climate change and other human-caused environmental changes that are decreasing phosphorus to levels that promote the formation of didymo blooms in many remote, otherwise pristine rivers worldwide.
Professor Brad Taylor is available to comment at Brad.Taylor@dartmouth.edu