[en] Piranhas are known to be sound-producing animals. Nevertheless, the biological significance of piranha calls remains unclear because sounds have been recorded only when specimens were held by hand or trapped in a gill net. These sounds are generated by rapid contractions of sonic muscles that insert on a broad tendon surrounding ventrally the cranial sac of the swimbladder.
The piranha swimbladder is thought to play an important role in sound production as an impedance-matching device and as a resonator. However, the vibratory capacities of the cranial and caudal sacs and the exact role of both sacs in sound production remain poorly understood. In this study, three sounds were each associated to a specific behaviour. The first sound (type 1) was produced during frontal display; it had numerous pulses and lasted 140±17 ms, with a fundamental frequency of 120±4 Hz. It corresponded to the sound made by hand-held fishes. The second sound (type 2) was produced during circling and fighting behaviour; it was a single pulse lasting 36±8 ms, with a fundamental frequency of 43±10 Hz. The third sound (type 3) corresponded to chasing behaviour and comprised three to four pulses, each lasting 3±1 ms, with a fundamental frequency of 1739±18 Hz. Using a laser vibrometer to study the swimbladder displacement when stimulated at different frequencies, it was demonstrated that the first two sounds corresponded to the swimbladder mechanism. By contrast, the third sound was associated with the jaw
mechanism. The vibrometer indicated that the swimbladder is a highly damping structure, simply copying the sonic muscle contraction rate. This study provides two interesting insights. First, it shows the relationships between three kinds of piranha sound and three specific behaviours. Second, using muscle stimulation at different rates, it shows which simultaneous conditions are required for production of sound in this species. Swimbladder calls were produced by a muscle contraction rate of approximately 100 Hz because this periodicity allowed the swimbladder to vibrate. At this frequency range, the contraction–relaxation cycles of the swimbladder muscles engendered wall displacements that had short amplitudes and with only a small variability between them.
Research center :
AFFISH-RC - Applied and Fundamental FISH Research Center - ULiège
Disciplines :
Zoology
Author, co-author :
Millot, Sandie
Vandewalle, Pierre ; Université de Liège - ULiège > Département des sciences et gestion de l'environnement > Département des sciences et gestion de l'environnement
Parmentier, Eric ; Université de Liège - ULiège > Département des sciences et gestion de l'environnement > Morphologie fonctionnelle et évolutive
Language :
English
Title :
Sound production in red-bellied piranhas (Pygocentrus nattereri, Kner): an acoustical, behavioural and morphofunctional study
Amorim, M. C. P., Fonseca, P. J. and Almada, V. C. (2003). Sound production during courtship and spawning of Oreochromis mossambicus: Male-female and male-male interactions. J. Fish Biol. 62, 658-672. (Pubitemid 38592329)
Archer, J. (1988). The Behavioural Biology of Aggression. Cambridge: Cambridge University Press.
Bergeijk, W. A. V. (1964). Directional and nondirectional hearing in fish. In Marine Bioacoustics (ed. W. N. Tavolga), pp. 281-299. New York: Pergamon Press.
Connaughton, M. A. (2004). Sound generation in the searobin (Prionotus carolinus), a fish with alternate sonic muscle contraction. J. Exp. Biol. 207, 1643-1654. (Pubitemid 38630494)
Connaughton, M. A., Fine, M. L. and Taylor, M. H. (2002). Weakfish sonic muscle: Influence of size, temperature and season. J. Exp. Biol. 205, 2183-2188.
Dagnélie, P. (1975). Théorie et méthodes statistiques. In Applications Agronomiques, Vol. 2, pp. 463. Gembloux: Presses Agronomiques de Gembloux.
Demski, L. S., Gerald, J. W. and Popper, A. N. (1973). Central and peripheral mechanisms of teleost sound production. Am. Zool. 13, 1141-1167.
Fine, M. L., Malloy, K. L., King, C. B., Mitchell, S. L. and Cameron, T. M. (2001). Movement and sound generation by the toadfish swimbladder. J. Comp. Physiol. A 187, 371-379. (Pubitemid 32731533)
Fine, M. L., King, C. B. and Cameron, T. M. (2009). Acoustical properties of the swimbladder in the oyster Opsanus tau. J. Exp. Biol. 212, 3542-3552.
Fowler, H. W. (1950). Peixes de agua doce do Brasil. Arq. Zool. Sao Paulo 6, 205-404.
Foxx, R. M. (1972). Attack preferences of the red-bellied piranha (Serrasalmus nattereri). Anim. Behav. 20, 280-283.
Goulding, M. (1980). The Fishes and the Forest: Explorations in Amazonian Natural History, 280 pp. Berkeley: University of California Press.
Grant, J. W. A. (1993). Whether or not to defend? The influence of resource distribution. Mar. Behav. Physiol. 23, 137-153.
Harris, G. G. (1964). Considerations on the physics of sound production by fishes. In Marine Bioacoustics (ed. W. N. Tavolga), pp. 233-247. New York: Pergamon Press.
Kastberger, G. (1981a). Economy of sound production in piranhas (Serrasalminae, Characidae): I. Functional properties of sonic muscles. Zool. Jb. Physiol. 85, 113-125.
Kastberger, G. (1981b). Economy of sound production in piranhas (Serrasalminae, Characidae): II. Functional properties of sound emitter. Zool. Jb. Physiol. 85, 393-411.
Ladich, F. and Bass, A. H. (2005). Sonic motor pathways in piranhas with a reassessment of phylogenetic patterns of sonic mechanisms among teleosts. Brain Behav. Evol. 66, 167-176. (Pubitemid 41291522)
Magurran, A. E. and Queiroz, H. L. (2003). Partner choice in piranha shoals. Behaviour 140, 289-299. (Pubitemid 36784764)
Malavasi, S., Valerio, C. and Torricelli, P. (2009). Courtship sounds and associated behaviours in the Canestrini's goby Pomatoschistus canestrinii. J. Fish Biol. 75, 1883-1887.
Markl, H. (1971). Sound production in Piranhas (Serrasalminae, Characidae). Z. Vgl. Physiol. 74, 39-56.
McCarthy, I. D., Carter, C. G. and Houlihan, D. F. (1992). The effetct of feeding hierarchy on individual variability in daily feeding of rainbow trout, Oncorhynchus mykiss. J. Fish Biol. 41, 257-263. (Pubitemid 23402347)
Meschkat, A. (1957). Von den stimmen der fische im Amazonas. Fischwirt 7, 67-68.
Onuki, A., Ohmori, Y. and Somiya, H. (2006). Spinal nerve innervation to the sonic muscle and sonic motor nucleus in red piranha, Pygocentrus nattereri (Characiformes, Ostariophysi). Brain Behav. Evol. 67, 111-122. (Pubitemid 43162714)
Pauly, D. (1994). Quantitative analysis of published data on the growth, metabolism, food consumption, and related features of the red-bellied piranha, Serrasalmus nattereri (Characidae). Environ. Biol. Fishes 41, 423-437.
Sazima, I. and Machado, F. A. (1990). Underwater observations of piranhas in western Brazil. Environ. Biol. Fishes 28, 17-31.
Schneider, H. (1964). Physiologische und morphologische Untersuchungen zur bioakustik der tigerfische (Pisces, Theraponidae). Z. Vgl. Physiol. 47, 493-558.
Tavolga, W. N. (1962). Mechanisms of sound production in the ariid catfishes, Galeichtkys and Bagre. Bull. Am. Mus. Nat. Hist. 124, 1-30.
Tavolga, W. N. (1971). Sound production and detection. In Fish Physiology, Vol. 5 (ed. W. S. Hoar and D. J. Randall), pp. 135-205. New York: Academic Press.
Tower, R. W. (1908). The production of sound in the drumfishes, the searobin and the toadfish. Ann. N. Y. Acad. Sci. 18, 149-180.
Uetanabaro, M., Wang, T. and Abe, A. S. (1993). Breeding behaviour of the redbellied piranha, Pygocentrus nattereri, in nature. Environ. Biol. Fishes 38, 369-371. (Pubitemid 2024157)
