Abstract
Mechanosensory lateral line afferents of weakly electric fish (Eigenmannia) responded to an object which moved parallel to the long axis of the fish with phases of increased spike activity separated by phases of below spontaneous activity. Responses increased with object speed but finally may show saturation. At increasingly greater distances the responses decayed as a power function of distance. For different object velocities the exponents (mean±SD) describing this response falloff were -0.71±0.4 (20 cm/s object velocity) and-1.9±1.25 (10 cm/s). Opposite directions of object movement may cause an inversion of the main features of the response histograms. In terms of peak spike rate or total number of spikes elicited, however, primary lateral line afferents were not directionally sensitive.
Central (midbrain) lateral line units of weakly electric fish (Apteronotus) showed a jittery response if an object moved by. In midbrain mechanosensory lateral line, ampullary, and tuberous units the response to a rostral-tocaudal object movement may be different from that elicited by a caudal-to-rostral object motion. Central units of Apteronotus may receive input from two or more sensory modalities. Units may be lateral line-tuberous or lateral line-ampullary. Multimodal lateral line units were OR units, i.e., the units were reliably driven by a unimodal stimulus of either modality. The receptive fields of central units demonstrate a weak somatotopic organization of lateral line input: anterior body areas project to rostral midbrain, posterior body areas project to caudal midbrain.
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Abbreviations
- EOD:
-
electric organ discharge
References
Bartels M, Münz H, Claas B (1990) Representation of lateral line and electrosensory systems in the midbrain of the axolotl, Ambystoma mexicanum. J Comp Physiol A 167:347–356
Bastian J (1976) The range of electrolocation: a comparison of electroreceptor responses and the responses of cerebellar neurons in a gymnotid fish. J Comp Physiol 108:193–210
Bastian J (1981a) Electrolocation I. How the electroreceptors of Apteronotus albifrons code for moving objects and other electrical stimuli. J Comp Physiol 144:465–479
Bastian J (1981b) Electrolocation. II. The effects of moving objects and other electrical stimuli on the activities of two categories of posterior lateral line lobe cells in Apteronotus albifrons. J Comp Physiol 144:481–494
Bastian J (1982) Vision and electroreception: Integration of sensory information in the optic tectum of the weekly electric fish Apteronotus albifrons. J Comp Physiol 147:287–297
Bastian J (1986) Electrolocation: Behavior, anatomy and physiology. In: Bullock TH, Heiligenberg W (eds) Electroreception. Wiley, New York, pp 577–612
Bastian J (1987a) Electrolocation in the presence of jamming signals: behavior. J Comp Physiol A 161:811–824
Bastian J (1987b) Electrolocation in the presence of jamming signals: electroreceptor physiology. J Comp Physiol A 161:825–836
Bastian J, Bratton B (1990) Descending control of electroreception. I. Properties of nucleus praeeminentialis neurons projecting indirectly to the electrosensory lateral line lobe. J Neurosci 10:1226–1240
Belbenoit P (1970) Conditionnement instrumental de électroperception des objets chez Gnathonemus petersii (Mormyridae, Teleostei, Pisces). Z Vergl Physiol 67:192–204
Bensouilah M, Denizot J-P (1991) Taste buds and neuromasts of Astyanax Jordani: Distribution and immunochemical demonstration of co-localized substance P and enkephalins. Eur J Neurosci 3:407–414
Blaxter JHS (1987) Structure and development of the lateral line. Biol Rev 62:471–514
Bleckmann H (1986) Role of the lateral line in fish behaviour. In: Pitcher TJ (ed) The behaviour of teleost fishes. Croom Helm, London, pp 177–202
Bleckmann H (1991) Orientation in the aquatic environment with aid of hydrodynamic stimuli. In: Pfannenstiel H-D (ed) Verh Dtsch Zool Ges 84. Gustav Fischer, Stuttgart, pp 105–124
Bleckmann H, Bullock TH (1989) Central physiology of the lateral line system, with special reference to elasmobranchs. In: Coombs S, Görner P, Münz H (eds) The mechanosensory lateral line. Neurobiology and evolution. Springer, New York, pp 387–408
Bleckmann H, Topp G (1981) Surface wave sensitivity of the lateral line system of the topminnow Aplocheilus lineatus. Naturwissenschaften 67:624–625
Bleckmann H, Weiss O, Bullock TH (1989) Physiology of lateral line mechanoreceptive regions in the elasmobranch brain. J Comp Physiol A 164:459–474
Bleckmann H, Breithaupt T, Blickhan R, Tautz J (1991) The time course and frequency content of hydrodynamic events caused by moving fish, frogs, and crustaceans. J Comp Physiol A 168:749–757
Bratton B, Bastian J (1990) Descending control of electroreception. II. Properties of nucleus praeeminentialis neurons projecting directly to the electrosensory lateral line lobe. J Neurosci 10:1241–1253
Campenhausen C von, Riess I, Weissert R (1981) Detection of stationary objects in the blind cave fish Anoptichthys jordani (Characidae). J Comp Physiol 143:369–374
Claas B, Münz H, Zittlau KE (1989) Direction coding in central parts of the lateral line system. In: Coombs S, Görner P, Münz H (eds) The mechanosensory lateral line. Neurobiology and evolution. Springer, New York, pp 409–419
Coombs S, Janssen J (1990) Behavioral and neurophysiological assessment of lateral line sensitivity in the mottled sculpin, Cottus bairdi. J Comp Physiol A 167:557–567
Coombs S, Montgomery J (1992) Fibers innervating different parts of the lateral line system of an Antarctic notothenioid, Trematomus bernacchii, have similar frequency responses, despite large variation in the peripheral morphology. Brain Behav Evol (in press)
Denton EJ, Gray JAB (1983) Mechanical factors in the excitation of clupeid lateral lines. Proc R Soc Lond B 218:1–26
Dijkgraaf S (1963) The functioning and significance of the lateral line organs. Biol Rev 38:51–106
Emde G von der (1990) Discrimination of objects through electrolocation in the weakly electric fish, Gnathonemus petersii. J Comp Physiol A 167:413–421
Emde G von der, Bleckmann H (1992) Extrem phase-sensitivity of afferents which innervate mormyromast electroreceptors. Naturwissenschaften 79:131–133
Enger PS, Szabo T (1965) Activity of central neurons involved in electroreception in some weakly electric fish (Gymnotidae). J Neurophysiol 28:800–818
Fiebig E (1988) Connections of the corpus cerebelli in the thornback guitarfish, Platyrhinoidis triseriata (Elasmobranchii): a study with WGA-HRP and extracellular granule cell recording. J Comp Neurol 268:567–583
Finger TE (1986) Electroreception in catfish. Behavior, anatomy, and electrophysiology. In: Bullock TH, Heiligenberg W (eds) Electroreception. Wiley, New York, pp 287–317
Hagiwara S, Szabo T, Enger PS (1965) Electroreceptor mechanisms in a high frequency weakly electric fish Sternarchus albifrons. J Neurophysiol 28:784–799
Harris GG, Bergeijk WA van (1962) Evidence that the lateral line organ responds to near-field displacements of sound sources in water. J Acoust Soc Am 34:1831–1841
Hartline PH, Newman EA (1981) Integration of visual and infrared information in bimodal neurons of the rattlesnake optic tectum. Science 213:789–791
Hassan E (1989) Hydrodynamic imaging of the surroundings by the lateral line of the blind cave fish Anoptichthys jordani. In: Coombs S, Görner P, Münz H (eds) The mechanosensory lateral line. Neurobiology and evolution. Springer, New York, pp 217–228
Heiligenberg W (1973) Electrolocation of objects in the electric fish Eigenmannia (Rhamphichthyidae, Gymnotidae). J Comp Physiol 87:137–164
Heiligenberg W (1974) Electrolocation and jamming avoidance in a Hypopygus (Rhamphichthyidae, Gymnotoidae), an electric fish with pulse-type discharges. J Comp Physiol 91:223–240
Heiligenberg W (1975) Electrolocation and jamming avoidance in the electric fish Gymnarchus niloticus (Gymnarchidae, Mormyriformes). J Comp Physiol 103:55–67
Heiligenberg W (1988) Electrosensory maps form a substrate for the distributed and parallel control of behavioral responses in weakly electric fish. Brain Behav Evol 31:6–16
Heiligenberg W (1990) Electrosensory systems in fish. Synapse 6:196–206
Heiligenberg W, Rose GJ (1987) The optic tectum of the gymnotiform electric fish, Eigenmannia: labeling of physiologically identified cells. Neurosci 22:331–340
Kalmijn AJ (1974) The detection of electric fields from inanimate and animate sources other than electric organs. In: Fessard A (ed) Handbook of sensory physiology. Vol. III/3. Springer, Berlin Heidelberg New York, pp 147–200
Kalmijn AJ (1988) Hydrodynamic and acoustic field detection. In: Atema J, Fay RR, Popper AN, Tavolga WN (eds) Sensory biology of aquatic animals. Springer, New York, pp 83–130
Knudsen EI (1976a) Midbrain responses to electroreceptive input in catfish: evidence of orientation preferences and somatotopic organization. J Comp Physiol 106:51–67
Knudsen EI (1976b) Midbrain units in catfish. Response properties to electroreceptive input. J Comp Physiol 109:315–335
Knudsen EI (1977) Distinct auditory and lateral line nuclei in the midbrain of catfishes. J Comp Neurol 173:417–432
Knudsen EI (1978) Functional organization in the electroreceptive midbrain of the catfish. J Neurophysiol 41:350–364
Kramer B (1990) Electrocommunication in teleost fishes. Behavior and experiments. Springer, New York, pp 1–240
Kroese ABA, Schellart NAM (1987) Evidence for velocity- and acceleration-sensitive units in the trunk lateral line of the trout. J Physiol (Lond) 393:29
Matsubara J, Heiligenberg W (1978) How well do electric fish electrolocate under jamming? J Comp Physiol 125:285–290
Metzner W, Heiligenberg W (1991) The coding of signals in the electric communication of the gymnotiform fish Eigenmannia: From electroreceptors to neurons in the torus semicircularis of the midbrain. J Comp Physiol A 169:35–150
Meyer JH (1982) Behavioral responses of weakly electric fish to complex impedances. J Comp Physiol 145:459–470
Münz H (1989) Functional organization of the lateral line periphery. In: Coombs S, Görner P, Münz H (eds) The mechanosensory lateral line. Neurobiology and evolution. Springer, new York, pp 285–298
Puzdrowski RL (1989) Peripheral distribution and central projections of the lateral-line nerves in goldfish, Carassius auratus. Brain Behav Evol 34:110–131
Roth A (1972) Wozu dienen die Elektrorezeptoren der Welse? J Comp Physiol 79:113–135
Schlegel PA (1973) Perception of objects in weakly electric fish Gymnotus carapo as studied in recordings from rhombencephalic neurons. Exp Brain Res 18:340–354
Schweitzer J (1986) Functional organization of the electroreceptive midbrain in an elasmobranch (Platyrhinoidis triseriata): A single unit study. J Comp Physiol A 158:43–58
Suga N (1967) Electrosensitivity of canal and free neuromast organs in a gymnotid fish. J Comp Neurol 131:453–457
Szabo T (1965) Sense organs of the lateral line system in some electric fish of the Gymnotidae, Mormyridae and Gymnarchidae. J Morphol 117:229–249
Tricas TC, Highstein SM (1991) Action of the octavolateralis efferent system upon the lateral line of free-swimming toadfish, Opsanus tau. J Comp Physiol A 169:25–37
Vischer HA (1989) The development of lateral-line receptors in Eigenmannia (Teleostei, Gymnotiformes) I. The mechanoreceptive lateral-line system. Brain Behav Evol 33:205–222
Wagner H, Takahashi T (1990) Neurons in the midbrain of the barn owl are sensitive to the direction of apparent acoustic motion. Naturwissenschaften 77:439–442
Wartzok D, Marks WB (1973) Directionally selective visual units recorded in optic tectum of the goldfish. J Neurophysiol 36:588–604
Weber T, Bleckmann H, Münz H (1991) Model experiments regarding the function of complex lateral line canals. Verh Dtsch Zool Ges 84. Gustav Fischer, Stuttgart, pp 461–462
Zittlau KE, Claas B, Münz H (1986) Directional sensitivity of lateral line units in the clawed toad Xenopus laevis Daudin. J Comp Physiol A 158:469–477
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Bleckmann, H., Zelick, R. The responses of peripheral and central mechanosensory lateral line units of weakly electric fish to moving objects. J Comp Physiol A 172, 115–128 (1993). https://doi.org/10.1007/BF00214721
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DOI: https://doi.org/10.1007/BF00214721