Short- and long-range synchronous activities in dimming detectors of the frog retina

HIROSHI ISHIKANE; AKIO KAWANA; MASAO TACHIBANA

doi:10.1017/S0952523899166033

Abstract

In the visual system, nearby neurons of similar functional type have a tendency to fire synchronously. Cross-correlation analysis of spike discharges recorded from pairs of neurons has revealed that the synchronized activity is frequently associated with oscillatory firing patterns. However, the underlying neural mechanisms and functions of synchronization and oscillations are not well understood. In the present study, we simultaneously recorded spike discharges from multiple OFF-sustained type ganglion cells with no antagonistic surround (the dimming detectors) of the frog retina using a planar multi-electrode array and analyzed the temporal properties of light-evoked spike discharges. With full-field, temporally modulated diffuse illumination, cross-correlation analysis revealed the presence of the synchronous oscillatory pattern. The strength of the synchronized activity decreased slightly with increased intercellular distance. Synchronized spike discharges were detected even in cell pairs more than 2 mm apart. The frequency of oscillations peaked at approximately 30 Hz. The shuffled cross-correlogram was nearly flat, indicating that the synchronous oscillatory activities are most probably of neural origin. When GABAA antagonists were applied to the retina, oscillations were suppressed almost completely and the strength of the synchronized activity decreased with increased intercellular distance more sharply than control. When small spot illumination was applied to the overlapping receptive fields of an adjacent cell pair, a weak synchronized activity was evoked without accompanying oscillations. The same cell pair generated a strong synchronized activity accompanied with oscillations with full-field illumination. Our results suggest that local synchronous activities are generated via short-range neural interactions, and that the oscillatory activities are induced by long-range neural interactions and may contribute to the establishment of synchrony between widely separated neuronal populations.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Watanabe, Shu-Ichi Koizumi, Amane Matsunaga, Shinya Stocker, Jonathan W. and Kaneko, Akimichi 2000. GABA-Mediated Inhibition Between Amacrine Cells in the Goldfish Retina. Journal of Neurophysiology, Vol. 84, Issue. 4, p. 1826.

Yoshida, Kazumichi Watanabe, Dai Ishikane, Hiroshi Tachibana, Masao Pastan, Ira and Nakanishi, Shigetada 2001. A Key Role of Starburst Amacrine Cells in Originating Retinal Directional Selectivity and Optokinetic Eye Movement. Neuron, Vol. 30, Issue. 3, p. 771.

KENYON, GARRETT T. MOORE, BARTLETT JEFFS, JANELLE DENNING, KATE S. STEPHENS, GREG J. TRAVIS, BRYAN J. GEORGE, JOHN S. THEILER, JAMES and MARSHAK, DAVID W. 2003. A model of high-frequency oscillatory potentials in retinal ganglion cells. Visual Neuroscience, Vol. 20, Issue. 5, p. 465.

Kenyon, G.T. Theiler, J. Marshak, D.W. Moore, B. Jeffs, J. and Travis, B.J. 2003. Firing correlations improve detection of moving bars. Vol. 2, Issue. , p. 1274.

Tachibana, Masao Ishikane, Hiroshi Gangi, Mie Arai, Itaru Asaka, Tomomitsu and Du, Jiulin 2003. The Neural Basis of Early Vision. p. 59.

Arai, Itaru Yamada, Yoshiyuki Asaka, Tomomitsu and Tachibana, Masao 2004. Light-Evoked Oscillatory Discharges in Retinal Ganglion Cells Are Generated by Rhythmic Synaptic Inputs. Journal of Neurophysiology, Vol. 92, Issue. 2, p. 715.

Kenyon, Garrett T. Theiler, James George, John S. Travis, Bryan J. and Marshak, David W. 2004. Correlated Firing Improves Stimulus Discrimination in a Retinal Model. Neural Computation, Vol. 16, Issue. 11, p. 2261.

Kenyon, G.T. Travis, B.J. Theiler, J. George, J.S. Stephens, G.J. and Marshak, D.W. 2004. Stimulus-Specific Oscillations in a Retinal Model. IEEE Transactions on Neural Networks, Vol. 15, Issue. 5, p. 1083.

Flynn, M. Abarbanel, H. and Kenyon, G. 2004. Neurally-Based Algorithms for Image Processing. p. 79.

Li, Liming Hayashida, Yuki and Yagi, Tetsuya 2005. Temporal properties of retinal ganglion cell responses to local transretinal current stimuli in the frog retina. Vision Research, Vol. 45, Issue. 2, p. 263.

Ishikane, Hiroshi Gangi, Mie Honda, Shoko and Tachibana, Masao 2005. Synchronized retinal oscillations encode essential information for escape behavior in frogs. Nature Neuroscience, Vol. 8, Issue. 8, p. 1087.

Furumiya, Tetsuo Ng, David C. Yasuoka, Koutaro Kagawa, Keiichiro Tokuda, Takashi Nunoshita, Masahiro and Ohta, Jun 2006. Functional verification of pulse frequency modulation-based image sensor for retinal prosthesis by in vitro electrophysiological experiments using frog retina. Biosensors and Bioelectronics, Vol. 21, Issue. 7, p. 1059.

MILLER, J.A. DENNING, K.S. GEORGE, J.S. MARSHAK, D.W. and KENYON, G.T. 2006. A high frequency resonance in the responses of retinal ganglion cells to rapidly modulated stimuli: A computer model. Visual Neuroscience, Vol. 23, Issue. 5, p. 779.

Fairhall, Adrienne L. Burlingame, C. Andrew Narasimhan, Ramesh Harris, Robert A. Puchalla, Jason L. and Berry, Michael J. 2006. Selectivity for Multiple Stimulus Features in Retinal Ganglion Cells. Journal of Neurophysiology, Vol. 96, Issue. 5, p. 2724.

Stephens, Greg J. Neuenschwander, Sergio George, John S. Singer, Wolf and Kenyon, Garrett T. 2006. See globally, spike locally: oscillations in a retinal model encode large visual features. Biological Cybernetics, Vol. 95, Issue. 4, p. 327.

Ding, Jin‐Dong and Weinberg, Richard J. 2007. Distribution of soluble guanylyl cyclase in rat retina. Journal of Comparative Neurology, Vol. 500, Issue. 4, p. 734.

Schadow, Jeanette Lenz, Daniel Thaerig, Stefanie Busch, Niko A. Fründ, Ingo Rieger, Jochem W. and Herrmann, Christoph S. 2007. Stimulus intensity affects early sensory processing: Visual contrast modulates evoked gamma-band activity in human EEG. International Journal of Psychophysiology, Vol. 66, Issue. 1, p. 28.

Xiao, Shufen 2009. Signals Spreading and Information Processing in the Outer Plexiform Layer of the Frog Retina. p. 1.

Jing, Wei Liu, Wen-Zhong Gong, Xin-Wei Gong, Hai-Qing and Liang, Pei-Ji 2010. Influence of GABAergic inhibition on concerted activity between the ganglion cells. NeuroReport, Vol. 21, Issue. 12, p. 797.

Gollisch, Tim and Meister, Markus 2010. Eye Smarter than Scientists Believed: Neural Computations in Circuits of the Retina. Neuron, Vol. 65, Issue. 2, p. 150.

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Short- and long-range synchronous activities in dimming detectors of the frog retina

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