Frog trade link to killer fungus revealed

8 November 2011 by Tamera Jones

The global trade in frogs, toads and other amphibians may have accidentally helped create and spread the deadly fungal disease, chytridiomycosis, which has devastated amphibian populations worldwide.

Panamanian golden frog

The Panamanian golden frog (Atelopus zeteki) is a critically endangered toad which is endemic to Panama

What's more, researchers say that unless the trade is regulated, even deadlier strains of the disease may soon emerge.

An international team of scientists, led by Dr Matthew Fisher from Imperial College London found that the trade may have let non-lethal strains of the chytrid fungus from different parts of the world come into contact with each other.

This means they've exchanged genes in a process called recombination, creating a new and lethal strain which has decimated frog populations around the world in recent years.

"It's likely that the amphibian trade has allowed different populations of the fungus to come into contact with each other, allowing recombination to occur," says Rhys Farrer from Imperial College London and ZSL's Institute of Zoology, lead author of the study, published in Proceedings of the National Academy of Sciences.

"This has created a hypervirulent strain leading to losses in amphibian biodiversity."

The chytrid fungus, or Batrachochytrium dendrobatidis (Bd) as it is sometimes called, infects the skins of amphibians like frogs, toads, salamanders and newts.

Declines in many amphibian populations around the world are due to the disease and over 200 species are suspected to have become extinct as a result. In Central America alone, chytridiomycosis has led to the loss of up to 40 per cent of wild amphibians including the Panamanian Golden Frog.

The horse has well and truly bolted, but to halt the further spread of this disease, we really need to increase global biosecurity.

- Dr Matthew Fisher, Imperial College London

Despite much research on the disease, scientists have struggled to figure out where it came from or explain how it spread. The problem is even more puzzling because some amphibians coexist alongside Bd with no sign of disease.

"This strongly suggested there may be more than one type of strain of chytrid fungus," says Farrer.

So, he and his colleagues decided to sequence and compare Bd genomes from 20 disease samples isolated from 11 amphibian species worldwide to find out more about the fungus' ancestry.

They found three different strains. One of these, the Global Panzootic Lineage (GPL), has made its way to at least five continents and has caused infections in North America, Central America, the Caribbean, Australia and Europe.

The researchers found evidence of gene exchange in this lineage, which turned out to be the deadliest of the three strains.

In one example, a captive breeding and reintroduction program to boost numbers of the endangered Mallorcan midwife toad may have helped Bd spread from captive African Cape clawed frogs to the toads.

The fact that they found three strains in just 20 samples also suggests Bd is much more diverse than previously thought.

"What's interesting is that they're not all causing disease," says Fisher. "Only one lineage is a killer, and it has evolved very recently". Scientists had until now thought there was just one strain of Bd.

Farrer, Fisher and their colleagues also found that the start of the decline of amphibians around the 1970s coincides with the emergence of the amphibian trade.

"The age of the lethal BdGPL lineage coincides with the start of the amphibian trade in the 20th century, when we started moving many frogs and toads around the world," says Fisher.

"The horse has well and truly bolted, but to halt the further spread of this disease, we really need to increase global biosecurity," says Fisher.

'Multiple emergences of genetically diverse amphibian-infecting chytrids include a globalised hypervirulent recombinant lineage' - Rhys A Farrer, Lucy A Weinert, Jon Bielby, Trenton WJ Garner, Francois Balloux, Frances Clare, Jaime Bosch, Andrew A Cunningham, Che Weldon, Louis H du Preez, Lucy Anderson, Sergei L Kosakovsky Pond, Revital Shahar-Golan, Daniel A Henk and Matthew C Fisher. PNAS, published 7 November 2011, doi