Invasive parasite robs fish of ability to swim, poses potential threat to endangered species


  • newswise-fullscreen Invasive parasite robs fish of ability to swim, poses potential threat to endangered species

    Blood-filled blisters on the tail of a blacktail shiner one day after 30-minute exposure to snails shedding larvae of Haplorchis pumilio. Fish died on day 3.

  • newswise-fullscreen Invasive parasite robs fish of ability to swim, poses potential threat to endangered species

    Blacktail shiner after exposure to Haplorchis pumilio larvae; showing random black spots on skin where larvae recently penetrated.

  • newswise-fullscreen Invasive parasite robs fish of ability to swim, poses potential threat to endangered species

    Cercarial larva of Haplorchis pumilio after emerging from infected snail.

  • newswise-fullscreen Invasive parasite robs fish of ability to swim, poses potential threat to endangered species

    Shell of the invasive Asian snail, Melanoides tuberculata, 1st intermediate host for Haplorchis pumilio.

  • newswise-fullscreen Invasive parasite robs fish of ability to swim, poses potential threat to endangered species

    Fountain darter with mouth stuck permanently open and blood in eye due to natural infection with Haplorchis pumilio.

Newswise — Researchers at Texas State University have identified an increasingly severe invasive parasite problem in the San Marcos and Comal Rivers that could impact native fish—including endangered species unique to Texas springs. 

One parasite has been under study since 1996, but in 2013, a student in the lab of David Huffman, a parasitologist in the Department of Biology at Texas State, discovered a new parasite, Haplorchis pumilio, was infecting fountain darters as well.  

"This newly arrived parasite infects the fins and jaw joints," said Huffman, who is one of more than 40 scientists throughout the Texas State University System working through the Texas Invasive Invasive Species Institute in Huntsville to study and develop strategies to deal with invasive species across the state. "The larvae of H. pumilio penetrate the skin and migrate through intervening tissues to get to the fins and the jaw, leaving behind a trail of trauma and inflammation. This worm is now proving to be a much more serious threat to fountain darters than the other parasite which receives most of the research attention."

“We’ve seen from experimental infections that the migrating larvae can rupture gall bladders, heart and other vital organs,” said Allison Scott, a graduate student working in the Huffman lab. "One fish I examined had a cyst behind its eye. You could see a large amount of blood in the eye. If soft tissue is in the path of a migrating larva, it just drills right through it. 

"Larvae that do not seek out the fins often end up encysting in the jaw, which stiffens the joint and prevents the mouth from closing," she said. "This interferes with feeding, and forces the fish to swim continuously to breathe."

Scott is now experimentally investigating the tissue pathology and stress indicators caused by H. pumilio in fish.

Fish that are not killed outright by H. pumilio face a challenging future, with the majority of the larvae encysting at the base of the tail, Huffman said. 

"The fin rays of a fish's tail have evolved to be individually bendable like double-jointed fingers, and are controlled by a complex array of muscles that give the fish fine control of fins for efficient swimming," Huffman said. "It's amazing these larvae target that specific spot, because that is where most of the finesse of swimming is generated. This parasite dramatically reduces the ability of a fish to control its fins, and recent swim-test research in our lab indicates that infected fish lose their ability to pursue food and to escape predators on a mathematically predictable 'dose-response' basis." 

In heavy experimental infections, the larvae create pronounced blisters on the tail, Scott said. In some instances, a blister bursts and kills the fish. 

"You don't see these blisters in nature, because affected fish are more susceptible to predation. Thus, when we’re sampling fish in the wild, we’re not sampling the whole range of parasite effects—we’re sampling only the survivors," Huffman said. "Unless researchers experimentally expose fish to documented levels of infection pressure, like we’re doing in our lab, they get a very limited picture of the range of impacts."

The source of the parasitic problem originates with an invasive Asian snail, identified by its distinctive spiral shell, which was introduced into local springs in the mid-20th century. The likely source of the snails was aquarium dumping by local residents. This snail is known to transmit more parasitic fluke diseases than any other snail in the world. Two of these parasites now heavily infect most fish species in the San Marcos and Comal springs, including the endangered fountain darter. In Laos and Vietnam, where fish are commonly eaten raw, both parasites also cause intestinal disease in humans. 

"Fortunately, it is very unlikely that local humans are going to contract these parasites, because they cook their fish," Huffman said. "On the other hand, if there are cats or dogs that are visiting fish cleaning stations, then it could become a veterinary problem. I've already warned one of the vets here to be on the lookout for it."


Comment/Share

Chat now!
5.77338