Summary
The African knife fish,Xenomystus nigri, is found to be sensitive to weak electric fields by the method of averaged evoked potentials from the brain. Slow waves and spikes were recorded in or near the lateral line area of the medulla and the torus semicircularis of the mesencephalon in response to long pulses (best > 50 ms) and low frequency sine waves (best ca. 10 Hz) of voltage gradients down to < 10 μV/cm. Evoked waves in the lateral line area are a sequence of negative and positive deflections beginning with a first peak at ca. 24 ms; in the torus semicircularis the first peak is at ca. 37 ms. Spikes are most likely in the torus between 50 and 80 ms after ON. At each recording locus there is a best axis of the homogeneous electric field and a better polarity. Effects of stimulus intensity, duration and repetition are described. The physiological properties are similar to those of ampullary receptor systems in mormyriforms, gymnotiforms and siluriforms.
Confirming Braford (1982),Xenomystus has a large medullary nucleus resembling the nucleus otherwise peculiar to mormyriforms, gymnotiforms and siluriforms and now called the electrosensory lateral line lobe (ELLL; formerly the posterior lateral line lobe). We describe the projections of anterior and posterior lateral line nerves by HRP applied to the proximal stump of a cut nerve. A descending central ramus of the anterior lateral line nerve and a lateral component of the ascending ramus of the posterior lateral line nerve end in part in the ELLL.
Electroreception, including the system of discrete central structures mediating it, is for the first time found to be less than an ordinal or even a family character, but apparently a characteristic of the subfamily Xenomystinae. Species of the other subfamily, Notopterinae as well as of the other families of osteoglossiforms (Osteoglossidae, Hiodontidae and Pantodontidae), lack the ELLL.Notopterus andPantodon are found to lack the evoked potential.
The positive finding of evoked activity to feeble electric field is found to be the most practical method for searching widely among fishes for the presence of the electrosense modality and its central pathways. The anatomical criterion of an ELLL can now be taken to be a good criterion for the presence of this sensory system. The absence of evoked response correlates well with the absence of an ELLL.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- ELLL :
-
electrosensory lateral line lobe
- HRP :
-
horseradish peroxidase
- TS :
-
torus semicircularis
References
Bass AH (1982) Evolution of the vestibulolateral lobe of the cerebellum in electroreceptive and non-electroreceptive teleosts. J Morphol (in press)
Bass AH, Hopkins CD (1982) Comparative aspects of brain organization of an African “wave” electric fish,Gymnarchus niloticus. J Morphol (in press)
Bell CC (1981) Central distribution of octavolateral afferents and efferents in a teleost (Mormyridae). J Comp Neurol 195:391–414
Bennett MVL (1965) Electroreceptors in mormyrids. Cold Spring Harbor Symp Quant Biol 30:245–262
Bennett MVL (1967) Mechanisms of electroreception. In: Cahn P (ed) Lateral line detectors. Indiana Univ Press, Bloomington, pp 313–393
Bennett MVL (1970) Comparative physiology: Electric organs. Annu Rev Physiol 32:471–528
Braford MR Jr (1982) African, but not Asian, notopterid fishes are electroreceptive: evidence from brain characters. Neurosci Lett (in press)
Bullock TH (1979) Processing of ampullary input in the brain: comparison of sensitivity and evoked responses among elasmobranch and siluriform fishes. J Physiol 75:397–407
Bullock TH (1982) Electroreception. Annu Rev Neurosci 5:121–170
Bullock TH, Northcutt RG, Bodznick DA (1982) Evolution of electroreception. Trends Neurosci 5:50–53
Carr CE, Maler L, Sas E (1982) Peripheral organization and central projections of the electrosensory nerve in gymnotiform fish. J Comp Neurol (in press)
Fink SV, Fink WL (1981) Interrelationships of the Ostariophysan fishes (Teleostei). Zool J Linn Soc 72:297–353
Greenwood PH (1973) Interrelationships of osteoglossomorphs. Zool J Linn Soc 53 (Suppl 1):307–332
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
Knudsen EI (1976) Midbrain responses to electroreceptive input in catfish: evidence of orientation preferences and somatotopic organization. J Comp Physiol 106:51–67
Maler L, Karten HJ, Bennett MVL (1973) The central connections of the posterior lateral line nerve ofGnathonemus petersi. J Comp Neurol 151:57–66
McCormick CA (1981) Comparative neuroanatomy of the octavolateralis area of fishes. In: Tavolga WN, Popper AN, Fay RR (eds) Hearing and sound communication in fishes. Springer, Berlin Heidelberg New York, pp 375–382
Mesulam M-M (1979) Tracing neural connections of human brain with selective silver impregnation. Arch Neurol 36:814–818
Nelson JS (1976) Fishes of the world. Wiley, New York
Pearson AA (1936) The acoustico-lateral centres and the cerebellum, with fibre connections, of fishes. J Comp Neurol 15:201–294
Scheich H, Bullock TH (1974) The detection of electric fields from electric organs. In: Fessard A (ed) Handbook of sensory physiology, vol III/3. Springer, Berlin Heidelberg New York, pp 201–256
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Bullock, T.H., Northcutt, R.G. A new electroreceptive teleost:Xenomystus nigri (Osteoglossiformes: Notopteridae). J. Comp. Physiol. 148, 345–352 (1982). https://doi.org/10.1007/BF00679019
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00679019