Design features for electric communication

CD Hopkins
Section of Neurobiology and Behavior, Cornell University, Ithaca, NY 14853, USA. cdh8@cornell.edu

How do the communication discharges produced by electric fish evolve to accommodate the unique design features for the modality? Two design features are considered: first, the limited range of signaling imposed on the electric modality by the physics of signal transmission from dipole sources; and second, the absence of signal echoes and reverberations for electric discharges, which are non-propagating electrostatic fields. Electrostatic theory predicts that electric discharges from fish will have a short range because of the inverse cube law of geometric spreading around an electrostatic dipole. From this, one predicts that the costs of signaling will be high when fish attempt to signal over a large distance. Electric fish may economize in signal production whenever possible. For example, some gymnotiform fish appear to be impedance-matched to the resistivity of the water; others modulate the amplitude of their discharge seasonally and diurnally. The fact that electric signals do not propagate, but exist as electrostatic fields, means that, unlike sound signals, electric organ discharges produce no echoes or reverberations. Because temporal information is preserved during signal transmission, receivers may pay close attention to the temporal details of electric signals. As a consequence, electric organs have evolved with mechanisms for controlling the fine structure of electric discharge waveforms.

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				V. L. Salazar and P. K. Stoddard Sex differences in energetic costs explain sexual dimorphism in the circadian rhythm modulation of the electrocommunication signal of the gymnotiform fish Brachyhypopomus pinnicaudatus J. Exp. Biol., March 15, 2008; 211(6): 1012 - 1020. [Abstract] [Full Text] [PDF]

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				M. E. Arnegard, B. S. Jackson, and C. D. Hopkins Time-domain signal divergence and discrimination without receptor modification in sympatric morphs of electric fishes J. Exp. Biol., June 1, 2006; 209(11): 2182 - 2198. [Abstract] [Full Text] [PDF]

				H. H. Zakon, Y. Lu, D. J. Zwickl, and D. M. Hillis Sodium channel genes and the evolution of diversity in communication signals of electric fishes: Convergent molecular evolution PNAS, March 7, 2006; 103(10): 3675 - 3680. [Abstract] [Full Text] [PDF]

				T. A. Terleph and P. Moller Effects of social interaction on the electric organ discharge in a mormyrid fish, Gnathonemus petersii (Mormyridae, Teleostei) J. Exp. Biol., July 15, 2003; 206(14): 2355 - 2362. [Abstract] [Full Text] [PDF]

				S. Schuster and N. Otto Sensitivity to novel feedback at different phases of a gymnotid electric organ discharge J. Exp. Biol., November 1, 2002; 205(21): 3307 - 3320. [Abstract] [Full Text] [PDF]

				M. L. McAnelly and H. H. Zakon Coregulation of Voltage-Dependent Kinetics of Na+ and K+ Currents in Electric Organ J. Neurosci., May 1, 2000; 20(9): 3408 - 3414. [Abstract] [Full Text] [PDF]

				S Schuster Changes in electric organ discharge after pausing the electromotor system of Gymnotus carapo J. Exp. Biol., January 5, 2000; 203(9): 1433 - 1446. [Abstract] [PDF]

				J. Sullivan, S Lavoue, and C. Hopkins Molecular systematics of the african electric fishes (Mormyroidea: teleostei) and a model for the evolution of their electric organs J. Exp. Biol., January 2, 2000; 203(4): 665 - 683. [Abstract] [PDF]

				M. Xu-Friedman and C. Hopkins Central mechanisms of temporal analysis in the knollenorgan pathway of mormyrid electric fish J. Exp. Biol., January 5, 1999; 202(10): 1311 - 1318. [Abstract] [PDF]

				J. Pettigrew Electroreception in monotremes J. Exp. Biol., January 5, 1999; 202(10): 1447 - 1454. [Abstract] [PDF]

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Design features for electric communication