Abstract
Wave-type weakly electric fish such as Eigenmannia produce continuous sinusoidal electric fields. When conspecifics are in close proximity, interaction of these electric fields can produce deficits in electrosensory function. We examined a neural correlate of such jamming at the level of the midbrain. Previous results indicate that neurons in the dorsal layers of the torus semicircularis can (1) respond to jamming signals, (2) respond to moving electrosensory stimuli, and (3) receive convergent information from the four sensory maps of the electrosensory lateral line lobe (ELL). In this study we recorded the intracellular responses of both tuberous and ampullary neurons to moving objects. Robust Gaussian-shaped or sinusoidal responses with half-height durations between 55 ms and 581 ms were seen in both modalities. The addition of ongoing global signals with temporal-frequencies of 5 Hz attenuated the responses to the moving object by 5 dB or more. In contrast, the responses to the moving object were not attenuated by the addition of signals with temporal frequencies of 20 Hz or greater. This occurred in both the ampullary and tuberous systems, despite the fact that the ampullary afferents to the torus originate in a single ELL map whereas the tuberous afferents emerge from three maps.
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Acknowledgements
The authors thank Jonathan Nizar for his help throughout this project. This work was supported by laboratory startup funds provided by Johns Hopkins University. The Howard Hughes foundation generously provided a postdoctoral training and teaching fellowship to Dr. John Ramcharitar, and undergraduate research support to Eric Tan. Special thanks to Dr. Bettina Diekamp for her technical assistance.
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Ramcharitar, J.U., Tan, E.W. & Fortune, E.S. Effects of global electrosensory signals on motion processing in the midbrain of Eigenmannia . J Comp Physiol A 191, 865–872 (2005). https://doi.org/10.1007/s00359-005-0008-2
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DOI: https://doi.org/10.1007/s00359-005-0008-2