Rainbow Trout's Own Bacteria Could Combat Coldwater Disease


After 15 years of research, scientists at the University of Idaho and Washington State University (WSU) have found a simple and effective method to fight the 'coldwater disease' in rainbow trout using some of the trout's own intestinal bacteria as health-giving probiotics.

These probiotics work by secreting a toxic protein that does not harm the fish but does kill the coldwater disease organism, Flavobacterium psychrophilum.

Douglas Call, professor in the WSU Paul G. Allen School for Global Animal Health, reported the findings in the publication Applied and Environmental Microbiology in January. The study was funded in part by the Western Regional Aquaculture Centre and the Idaho State Board of Education.

"Coldwater disease is the number one bacterial illness affecting US trout aquaculture and to a lesser extent coho salmon," said Call. "Once an outbreak starts, the only way we've had to treat it has been with antibiotics."

"The problem with antibiotics is that they can lead to bacterial resistance and also contaminate the water and soil," he stressed. "Only two antibiotics are approved for use and one, florfenicol, is particularly nasty and persists in the environment for a very long time."

He explained that probiotics could be a cheap and effective alternative to antibiotics – and welcome news to the global salmonid aquaculture industry whose annual production tops out at more than USD13.7 billion.

How does it work?

Kenneth Cain, professor and associate director of the Aquaculture Research Institute at University of Idaho, recently discovered the probiotic, a now patented strain of Enterobacter bacteria called C6-6.

Probiotics, broadly speaking, are live bacteria and yeast that are beneficial to health. Lactobacilli bacteria, for example, are commonly used in yogurt and livestock feed to help promote disease resistance and overall health. Cain said probiotics are commercialized for use in European fisheries, but have only recently been considered for US aquaculture.

To find the C6-6 probiotic, Cain and his colleagues painstakingly searched through 318 strains of bacteria from the GI tracts of trout until they identified those that could kill the coldwater disease microorganism. He chose to examine the trout's native gut bacteria because such strains were able to survive in the fish's digestive system.

Subsequent field trials showed significantly reduced mortality rates from the disease in fish that were fed strain C6-6.

Douglas Call, professor at the WSU and expert in bacterial molecular biology, explains, "We found C6-6 produces a toxic protein called an entericidin, which inhibits the coldwater bacteria."
"It could also present new opportunities for treatments against closely related pathogens," he added.

Moreover, it is an economical method.

"The bacteria that produce the entericidin are fast growing, cheap to produce and easy to put on food for the fish – all the attributes of an ideal preventative treatment," said Call.

A combined approach

Although coldwater disease occurs in the wild, Cain pointed out it is most prevalent in commercial trout and salmon hatcheries where crowding and stress lead to frequent outbreaks – a point of concern for Pacific Northwest growers.

Idaho trout farms produce about 75 percent of US and nearly 50 percent of worldwide trout harvest. Neighbouring Washington State leads the nation in production of trout eggs, a commodity sold to hatcheries around the globe.

"It costs the Idaho trout farm industry and Washington aquaculture facilities over USD 10 million each year to combat coldwater disease," Cain emphasized. "Controlling it will take more than one tool."

He recently patented a vaccine for the disease that is in the licensing process. He and Call agree that vaccinating fish to prevent coldwater disease, followed by the feeding of probiotics to limit its spread, would be beneficial.

Thanks to the discovery of the C6-6 entericidin, Call said he is hopeful for regulatory approval and commercial licensing of the probiotic as well.

"If C6-6 is as effective as our research is showing, it will reduce disease losses for fish producers, improve animal welfare and reduce the demand for antibiotics in aquaculture," he concluded.

Article cited from: http://goo.gl/6TbPRB 




  1. Waste No Waste: Time to Embrace Biogas
  2. Is Big Gas finally learning to love biogas?
  3. We need to get behind Renewable Natural Gas
  4. Difference between a Turbo and Positive Displacement Blower
  5. The Difference between Methane and Natural Gas
  6. First Dairy Biogas Project in Connecticut
  7. Does Renewable Natural Gas Have a Future in Energy?
  8. Biogas Offtake Opportunities For Digesters
  9. Wisconsin Dairy Begins Production of Renewable Natural Gas
  10. Anaerobic Digestion Sector Forming a Clearer Picture
  11. Brightmark to Expand Western New York Dairy Biogas Project
  12. Biogas - The Energy Wonder That's Under Our Noses
  13. Power Generation Achieved by a Self-Assembled Biofuel Cell
  14. Less Carbon Dioxide from Natural Gas
  15. Project Uses Renewable Electricity for RNG Production
  16. Smithfield Hog Farm Provides Natural Gas to Missouri City
  17. From Waste to Gas
  18. Gas Clash Threatens Australian Export
  19. Maximizing Opportunities of Anaerobic Digestion from Wastewater
  20. Catalyst to Speed up Conversion of Biomass to Biofuel
  21. How It Works: Ethanol
  22. Anaerobic Digestion - the Next Big Renewable Energy Source
  23. Anaerobic Additions
  24. Three (3) Tech Solutions for Modern Landfills
  25. The Costs and Benefits of Anaerobic Digesters
  26. Bacteria Farts Power Wastewater Plant in Fort Wayne
  27. Europe’s First Poultry Manure Biogas Plant
  28. Electricity Using Pig Manure
  29. $38-Million Biodigester coming to Grand Rapids
  30. Biochar Could Benefit Anaerobic Digestion of Animal Manure

For additonal reading, please visit us at: News Worthy

Difference between a Turbo and Positive Displacement Blower