Researchers closer to understanding the evolution of sound production in fish

December 15, 2011

RICHMOND, Va. (Dec. 15, 2011) - An international team of researchers studying sound production in perch-like fishes has discovered a link between two unrelated lineages of fishes, taking researchers a step closer to understanding the evolution of one of the fastest muscles in vertebrates.

Understanding the evolution of such fast muscles has been difficult for researchers because slow movement of a swimbladder does not generate sound.

In a study published online Nov. 29 in the journal Frontiers in Zoology, Virginia Commonwealth University biologists, together with researchers Hin-Kiu Mok, Ph.D., at the National Sun Yat-sen University in Taiwan, and Eric Parmentier, Ph.D., at the Université de Liège in Belgium, have found that the pearl-perch belonging to the fish order Perciformes utilizes a hybrid system with characteristics of slow and fast systems. The findings suggest an intermediate condition in the evolution of superfast sonic muscles that drive swimbladder vibration directly. Perciforms are one of the largest orders of vertebrates.

"This work for the first time demonstrates an intermediate condition in the potential evolution of these superfast muscles," said investigator Michael Fine, Ph.D., professor of biology at VCU, who served as corresponding author for the study.

"It's sort of like finding a fossil whale with leg bones indicating affinity to a terrestrial vertebrate, or a dinosaur with feathers indicating potential steps in the evolution of reptiles into birds," he said.

According to Fine, a number of fish produce sounds by contracting superfast muscles that vibrate the swimbladder to produce aggressive and courtship calls. For example, in the oyster toadfish found on the east coast of the United States, swimbladder muscles routinely contract more than 200 times a second when a male is calling for a mate. Fine and his colleagues recently found a group of fishes that produce sound by using slow muscles to pull the swimbladder, which then snaps back - like a rubber band - to produce sound. In this case the pearl perch has a hybrid system that uses a slow system but actually pulls the swimbladder forward with a fast muscle. The fish has a tendon that gets stretched and causes the bladder to snap back, producing the loud part of the sound.

"What is special about this perciform is that its sound producing system appears to have intermediate characteristics between slow systems which are only known in ophidiiform fishes, and fast muscles present in different groups of fishes," he said.
-end-
The work was supported in part by a grant from the National Science Council of Taiwan and the F.R.S.-FNRS in Belgium.

About VCU and the VCU Medical Center: Virginia Commonwealth University is a major, urban public research university with national and international rankings in sponsored research. Located on two downtown campuses in Richmond, VCU enrolls more than 31,000 students in 216 certificate and degree programs in the arts, sciences and humanities. Sixty-nine of the programs are unique in Virginia, many of them crossing the disciplines of VCU's 13 schools and one college. MCV Hospitals and the health sciences schools of Virginia Commonwealth University compose the VCU Medical Center, one of the nation's leading academic medical centers. For more, see http://www.vcu.edu.

Virginia Commonwealth University

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