Convergent evolution of molecules in electric fish

Mar 03, 2006
Convergent evolution of molecules in electric fish
Weakly electric fish from South America, Sternarchorhynchus mormyrus, and Africa, Campylomormyrus phantasticus. Both fish evolved the ability to generate and sense electric fields. These two species also independently evolved curved jaws for bottom feeding. Electric discharges for each species are indicated. Images courtesy of Carl D. Hopkins and John Sullivan.

Having a set of extra genes gave fish on separate continents the ability to evolve electric organs, report researchers from The University of Texas at Austin.

Dr. Harold Zakon and colleagues, in a paper recently published in Proceedings of the National Academy of Sciences, show that African and South American groups of fish independently evolved electric organs by modifying sodium channel proteins typically used in muscle contraction.

Mutations in sodium channel proteins can cause serious muscular disorders, epilepsy and heart problems in humans and other vertebrates.

But fish have two copies of many of their genes, and Zakon found that the duplicate sodium channel gene could mutate and evolve without harming the fish.

“The spare gene gave [the electric fish] a little bit of evolutionary leeway,” says Zakon, professor of neurobiology. “This is really one of the first cases that the ancestral gene duplication in fish has actually been linked to a gene that has been freed up and evolving in accordance with a ‘new lifestyle.’”

Zakon and colleagues looked at two sodium channel genes in the electric organs and muscles in electric and non-electric fish. Electric fish use their electric organs, which are modified muscles, to communicate with each other and sense their environment.

The researchers found that electric fishes expressed one of the sodium channel genes in their electric organs only, while non-electric fish express both genes in their muscles.

“Most fish have both genes in the muscle, but as the new electric organ was evolving, the sodium channel—by being lost from the muscle—became devoted to the electric organ,” Zakon says. “So two times, independently, the gene has been ‘lost’ from the muscle. It’s no longer able to turn on in a cell that for millions of years it turned on in, and now it’s turning on in this new organ.”

When the research team looked at the sodium channel protein sequences, they found that some of the mutations occurred at the same or very close to sites in the protein where mutations have been shown to cause disease in humans.

“Functionally important parts of this molecule are changing in order to change the electrical discharge in the fish—changes that would be detrimental in a human muscle,” says Zakon.

Looking at the convergent evolution of sodium channels in these fish helps neurobiologists identify important parts of these proteins relevant to human health, adds Zakon.

“When natural selection is acting to cause changes in a part of a molecule, you know it’s functionally important,” he says. “Natural selection can start showing you the important parts of molecules. We took the evolutionary approach, which is very compatible with the clinical approach.”

The research team included evolutionary biologist Dr. David Hillis, graduate student Derrick Zwickl and research associate Ying Lu.

Source: University of Texas at Austin

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