Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-27T11:55:56.936Z Has data issue: false hasContentIssue false
  • English
  • Français

Muscimol and baclofen differentially suppress retinotopic and nonretinotopic responses in visual cortex

Published online by Cambridge University Press:  03 February 2006

TAKUJI KASAMATSU ,
KEIKO MIZOBE  and
ERICH E. SUTTER
TAKUJI KASAMATSU
Affiliation:
The Smith-Kettlewell Eye Research Institute, San Francisco, California
KEIKO MIZOBE
Affiliation:
The Smith-Kettlewell Eye Research Institute, San Francisco, California Present address: Keiko Mizobe, Department of Ophthalmology, Kyoto Prefectural University of Medicine, Kamigyo-ku, Kyoto, 602-8566 Japan
ERICH E. SUTTER
Affiliation:
The Smith-Kettlewell Eye Research Institute, San Francisco, California
Get access Rights & Permissions [Opens in a new window]

Abstract

This study relates to local field potentials and single-unit responses in cat visual cortex elicited by contrast reversal of bar gratings that were presented in single, double, or multiple discrete patch (es) of the visual field. Concurrent stimulation of many patches by means of the pseudorandom, binary m-sequence technique revealed interactions between their respective responses. An analysis identified two distinct components of local field potentials: a fast local component (FLC) and a slow distributed component (SDC). The FLC is thought to be a primarily postsynaptic response, as judged by its relatively short latency. It is directly generated by thalamocortical volleys following retinotopic stimulation of receptive fields of a small cluster of single cells, combined with responses to recurrent excitation and inhibition derived from the cells under study and immediately neighboring cells. In contrast, the SDC is thought to be an aggregate of dendritic potentials related to the long-range lateral connections (i.e. long-range coupling). We compared the suppressive effects of a GABAA-receptor agonist, muscimol, on the FLC and SDC with those of a GABAB-receptor agonist, baclofen, and found that muscimol more strongly suppressed the FLC than the SDC, and that the reverse was the case for baclofen. The differential suppression of the FLC and SDC found in the present study is consistent with the notion that intracortical electrical signals related to the FLC terminate on the somata and proximal/basal dendrites, while those related to the SDC terminate on distal dendrites.

Keywords

Long-range lateral interactionsGABAA- and GABAB-receptorsFast local potentialsSlow distributed potentialsBinary m-sequenceMulti-input nonlinear systems analysisCat striate cortex
Type
Research Article
Information
Visual Neuroscience , Volume 22 , Issue 6 , November 2005 , pp. 839 - 858
Copyright
© 2005 Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Angelucci, A., Levitt, J.B., Walton, E.J.S., Hupé, J.-M., Bullier, J., & Lund, J.S. (2002). Circuits for local and global signal integration in primary visual cortex. Journal of Neuroscience 22, 86338646.Google Scholar
Berman, N.J., Douglas, D.J., & Martin, K.A.C. (1992). GABA-mediated inhibition in the neural networks of visual cortex. Progress in Brain Research 90, 443476.Google Scholar
Bonanno, G. & Raiteri, M. (1993). Multiple GABAB receptors. Trends in Pharmacological Science 14, 259261.CrossRefGoogle Scholar
Bowery, N.G. (1993). GABAB receptor pharmacology. Annual Review of Pharmacology and Toxicology 33, 109147.CrossRefGoogle Scholar
Bowery, N.G., Hudson, A.L., & Price, G.W. (1987). GABAA and GABAB receptor site distribution in the rat central nervous system. Neuroscience 20, 365383.CrossRefGoogle Scholar
Bowery, N.G., Bettler, B., Froestl, W., Gallagher, J.P., Marshall, F., Raiteri, M., Bonner, T.I., & Enna, S.J. (2002). International Union of Pharmacology. XXXIII. Mammalian γ-aminobutyric AcidB receptors: structure and function. Pharmacological Reviews 554, 247264.Google Scholar
Bringuier, V., Chavane, F., Glaeser, L., & Fregnac, Y. (1999). Horizontal propagation of visual activity in the synaptic integration field of area 17 neurons. Science 283, 695699.CrossRefGoogle Scholar
Cavanaugh, J.R., Bair, W., & Movshon, J.A. (2002a). Nature and integration of signals from the receptive field center and surround in macaque V1 neurons. Journal of Neurophysiology 88, 25302546.Google Scholar
Cavanaugh, J.R., Bair, W., & Movshon, J.A. (2002b). Selectivity of spatial distribution of signals from the receptive field surround in macaque V1 neurons. Journal of Neurophysiology 88, 25472556.Google Scholar
Chen, C.C., Kasamatsu, T., Polat, U., & Norcia, A.M. (2001). Contrast response characteristics of long-range lateral interactions in cat striate cortex. NeuroReport 12, 655661.CrossRefGoogle Scholar
Chisum, H.J., Mooser, F., & Fitzpatrick, D. (2003). Emergent properties of layer 2/3 neurons reflect the collinear arrangement of horizontal connections in tree shrew visual cortex. Journal of Neuroscience 23, 29472960.Google Scholar
Connors, B.W. (1992). GABAA- and GABAB-mediated processes in visual cortex. Progress in Brain Research 90, 335348.CrossRefGoogle Scholar
Connors, B.W., Malenka, R.C., & Silva, L.R. (1988). Two inhibitory postsynaptic potentials, and GABAA and GABAB receptor-mediated responses in neocortex of rat and cat. Journal of Physiology (London) 406, 443468.CrossRefGoogle Scholar
Das, A. & Gilbert, C.D. (1999). Topography of contextual modulations mediated by short-range interactions in primary visual cortex. Nature 399, 655661.Google Scholar
Douglas, R.J. & Martin, K.A.C. (1991). Opening the grey box. Trends in Neuroscience 14, 286293.CrossRefGoogle Scholar
Duffy, F.H., Snodgrass, S.R., Burchfiel, J.L., & Conway, J.L. (1976). Bicuculline reversal of deprivation amblyopia in the cat. Nature 260, 256257.CrossRefGoogle Scholar
Edgar, P.P. & Schwartz, R.D. (1990). Localization and characterization of 35S-t-butylbicyclophosphorothionate binding in rat brain: An autoradiographic study. Journal of Neuroscience 10, 603612.Google Scholar
Fiorani Jr., M., Rosa, M.G.P., Gattass, R., & Rocha-Miranda, C.E. (1992). Dynamic surrounds of receptive fields in primate cortex: A physiological basis for perceptual completion? Proceedings of the National Academy of Sciences of the U.S.A. 89, 85478551.CrossRefGoogle Scholar
Fitzpatrick, D. (2000). Seeing beyond the receptive field in the primary visual cortex. Current Opinion in Neurobiology 10, 438443.CrossRefGoogle Scholar
Froestl, W. & Mickel, S.J. (1997). Chemistry of GABAB modulators. In The GABA Receptors, ed. Enna, S.J. & Bowery, N.G., pp. 271296. Totowa, New Jersey: Humana Press.CrossRef
Gil, Z., Connors, B.W., & Amitai, Y. (1997). Differential regulation of neocortical synapses by neuromodulators and activity. Neuron 19, 679686.CrossRefGoogle Scholar
Gilbert, C.D., Hirsch, J.A., & Wiesel, T.N. (1990). Lateral interactions in visual cortex. In Cold Spring Harbor Symposia on Quantitative Biology. Volume 55: The Brain, ed. Stryker, M.P., pp. 663677. Plainview, New York: Cold Spring Harbor Laboratory Press.CrossRef
Girard, P., Hupé, J.M., & Bullier, J. (2001). Feedforward and feedback connections between areas V1 and V2 of the monkey have similar rapid conduction velocities. Journal of Neurophysiology 85, 13281331.Google Scholar
Grinvald, A., Tsío, D.Y., Frosting, R.D., Lieke, E., Arieli, A., & Hildesheim, R. (1989). Optical imaging of neuronal activity in the visual cortex. In Neural Mechanisms of Visual Perception, ed. Lam, D.M.K. & Gilbert, C.D., pp. 117136. The Woodlands, Texas: Portfolio Publishing.
Gu, Q., Perez-Velazquez, J.L., Angelides, K.J., & Cynader, M.S. (1993). Imunocytochemical study of GABAA receptors in the cat visual cortex. Journal of Comparative Neurology 333, 94108.CrossRefGoogle Scholar
Hild, W. & Tasaki, I. (1962). Morphological and physiological properties of neurons and glia cells in tissue culture. Journal of Neurophysiology 25, 277304.Google Scholar
Hill, D.R. (1985). GABAB receptor modulation of adenylate cyclase in rat brain slices. British Journal of Pharmacology 84, 249257.Google Scholar
Hupé, J.M., James, A.C., Girard, P., & Bullier, J. (2001). Response modulations by static texture surround in area V1 of the macaque monkey do not depend on feedback connections from V2. Journal of Neurophysiology 85, 146163.Google Scholar
Imamura, K. & Kasamatsu, T. (1991). Ocular dominance plasticity restored by NA infusion to aplastic visual cortex of anesthetized and paralyzed kittens. Experimental Brain Research 87, 309318.Google Scholar
Kapadia, M.K., Ito, M., Gilbert, C.D., & Westheimer, G. (1995). Improvement in visual sensitivity by changes in local context: Parallel studies in human observers and in V1 of alert monkeys. Neuron 15, 843856.CrossRefGoogle Scholar
Kapadia, M.K., Westheimer, G., & Gilbert, C.D. (1999). Dynamics of spatial summation in primary visual cortex of alert monkeys. Proceedings of the National Academy of Sciences of the U.S.A. 96, 1207312078.CrossRefGoogle Scholar
Karbon, E.W. & Enna, S.J. (1985). Characterization of the relationship between gamma-aminobutyric acid B agonists and transmitter-coupled cyclic nucleotide-generating systems in rat brain. Molecular Pharmacology 27, 5359.Google Scholar
Kasamatsu, T. & Schmidt, E.K. (1997). Continuous and direct infusion of drug solutions in the brain of awake animals: implementation, strengths and pitfalls. Brain Research Protocols 1, 5769.CrossRefGoogle Scholar
Kasamatsu, T., Itakura, T., & Jonsson, G. (1981). Intracortical spread of exogenous catecholamines: Effective concentration for modifying cortical plasticity. Journal of Pharmacology and Experimental Therapeutics 217, 841850.Google Scholar
Kasamatsu, T., Kitano, M., Sutter, E.E., & Norcia, A.M. (1998). Lack of lateral inhibitory interactions in visual cortex of monocularly deprived cats. Vision Research 38, 112.Google Scholar
Kasamatsu, T., Zhu, Z., Chang, M.S., Ishida, Y., & Miller, R. (2004). Collinear facilitation and suppression in long-range lateral interactions in cat striate cortex. Abstract Society for Neuroscience, 34th Annual Meeting, 18.8.
Kaupmann, K., Huggel, K., Heid, J., Flor, P.J., Bischoff, S., Mickel, S.J., McMaster, G., Angst, C., Bittiger, H., Froestl, W., & Bettler, B. (1997). Expression cloning of GABAB receptors uncovers similarity to metabotropic glutamate receptors. Nature 386, 239246.CrossRefGoogle Scholar
Kitano, M., Kasamatsu, T., Norcia, A.M., & Sutter, E.E. (1995). Spatially distributed responses induced by contrast reversal in cat visual cortex. Experimental Brain Research 104, 297309.Google Scholar
Kitano, M., Niiyama, K., Kasamatsu, T., Sutter, E.E., & Norcia, A.M. (1994). Retinotopic and nonretinotopic field potentials in cat visual cortex. Visual Neuroscience 11, 953977.CrossRefGoogle Scholar
Knierim, D.C. & Van Essen, D.C. (1992). Neuronal responses to static texture patterns in area V1 of the alert macaque monkey. Journal of Neurophysiology 67, 961980.Google Scholar
Lambert, N.A. & Wilson, W.A. (1996). High-threshold Ca2+ currents in rat hippocampal interneurones and their selective inhibition by activation of GABAB receptors. Journal of Physiology 492, 115127.CrossRefGoogle Scholar
Levick, W.R. (1972). Another tungsten microelectrode. Medical and Biological Engineering 10, 510515.CrossRefGoogle Scholar
Levitt, J.B. & Lund, J.S. (1997). Contrast dependence of contextual effects in primate visual cortex. Nature 387, 7376.CrossRefGoogle Scholar
Levitt, J.B. & Lund, J.S. (2002). The spatial extent over which neurons in macaque striate cortex pool visual signals. Visual Neuroscience 19, 439452.CrossRefGoogle Scholar
Li, C.-Y. & Li, W. (1994). Extensive integration field beyond the classical receptive field of cat's striate cortical neurons—classification and tuning properties. Vision Research 34, 23372355.Google Scholar
Lüscher, C., Jan, L.Y., Stoffel, M., Malenka, R.C., & Nicoll, R.A. (1997). G protein-coupled inwardly rectifying K+ channels (GIRKs) mediate postsynaptic but not presynaptic transmitter actions in hippocampal neurons. Neuron 19, 687695.CrossRefGoogle Scholar
Martinelli, G.P., Holstein, G.R., Pasik, P., & Cohen, B. (1992). Monoclonal antibodies for ultractructural visualization of L-baclofen-sensitive GABAB receptor sites. Neuroscience 46, 2333.CrossRefGoogle Scholar
McGuire, B.A., Gilbert, C.D., Rivlin, P.K., & Wiesel, T.N. (1991). Targets of horizontal connections in macaque primary visual cortex. Journal of Comparative Neurology 305, 370392.CrossRefGoogle Scholar
Misgeld, U., Bijak, M., & Jarolimek, W. (1995). A physiological role for GABAB receptors and the effects of baclofen in the mammalian central nervous system. Progress in Neurobiology 46, 423462.CrossRefGoogle Scholar
Mizobe, K., Kasamatsu, T., Polat, U., & Norcia, A.M. (1996b). Contrast and context-dependent modulation of single-cell responses elicited in cat area 17 by compound stimuli. Society for Neuroscience Abstracts 22, 642.Google Scholar
Mizobe, K., Polat, U., Kasamatsu, T., & Norcia, A.M. (1996a). Lateral masking reveals facilitation and suppression from the same single cells in cat area 17. Investigative Ophthalmology and Visual Science Abstracts 37, S483.Google Scholar
Mizobe, K., Polat, U., Pettet, M.W., & Kasamatsu, T. (2001). Facilitation and suppression of single striate-cell activity by spatially discrete pattern stimuli presented beyond the receptive field. Visual Neuroscience 18, 377391.CrossRefGoogle Scholar
Mizobe, K., Schmidt, E., & Kasamatsu, T. (1995a). Muscimol suppression of contrast-reversal responses elicited by retinotopic and non-retinotopic visual-field stimulation. Investigative Ophthalmology and Visual Science Abstracts 36, S693.Google Scholar
Mizobe, K., Schmidt, E., & Kasamatsu, T. (1995b). Muscimol and baclofen differently suppress retinotopic and non-retinotopic cortical responses. Society for Neuroscience Abstracts 21, 1655.Google Scholar
Polat, U., Mizobe, K., Pettet, M.W., Kasamatsu, T., & Norcia, A.M. (1998). Collinear stimuli regulate visual response depending on cell's contrast threshold. Nature 391, 580584.Google Scholar
Reiter, H.O. & Stryker, M.P. (1988). Neural plasticity without postsynaptic activation potentials: Less active inputs become dominant when kitten visual cortical cells are pharmacologically inhibited. Proceedings of the National Academy of Sciences of the U.S.A. 85, 36233627.CrossRefGoogle Scholar
Sceniak, M.P., Ringach, D.L., Hawken, M.J., & Shapley, R. (1999). Contrast's effect on spatial summation by macaque V1 neurons. Nature Neuroscience 2, 733739.CrossRefGoogle Scholar
Sceniak, M.P., Hawken, M.J., & Shapley, R. (2001). Visual spatial characterization of macaque V1 neurons. Journal of Neurophysiology 85, 18731887.Google Scholar
Shirokawa, T. & Kasamatsu, T. (1986). Concentration-dependent suppression by β-adrenergic antagonists of the shift in ocular dominance following monocular deprivation in kitten visual cortex. Neuroscience 18, 10351046.CrossRefGoogle Scholar
Sillito, A.M., Kemp, J.A., & Blakemore, C. (1981). The role of GABAergic inhibition in the cortical effects of monocular deprivation. Nature 290, 318320.CrossRefGoogle Scholar
Sillito, A.M., Grieve, K.L., Jones, H.E., Cudeiro, J., & Davis, J. (1995). Visual cortical mechanisms detecting focal orientation discontinuities. Nature 378, 492496.CrossRefGoogle Scholar
Stettler, D.D., Das, A., Bennett, J., & Gilbert, C.D. (2002). Lateral connectivity and contextual interactions in macaque primary visual cortex. Neuron 36, 739750.CrossRefGoogle Scholar
Sutter, E.E. (1991). The fast m-transforms: A fast computation of cross correlations with binary m-sequences. SISM Journal on Computing 20, 686694.CrossRefGoogle Scholar
Sutter, E.E. (1992). A deterministic approach to nonlinear systems analysis. In Nonlinear Vision: Determination of Neural Receptive Fields, Function and Networks, ed. Pinter, R.B. & Nabet, B., pp. 171220. Boca Raton, Florida: CRC Press.
Sutter, E.E. & Tran, D. (1992). The field topography of ERG components in man: I. The photic luminance response. Vision Research 32, 433446.CrossRefGoogle Scholar
Takahashi, T., Kajikawa, Y., & Tsujimoto, T. (1998). G-protein-coupled modulation of presynaptic calcium currents and transmitter release by a GABAB receptor. Journal of Neuroscience 18, 31383146.Google Scholar
Tunnicliff, G., Roger, C.J., & Youngs, T.L. (1988). Inhibition of neuronal membrane GABAB receptor binding by GABA structural analogues. International Journal of Biochemistry 20, 179182.CrossRefGoogle Scholar
Vigot, R. & Batini, C. (1997). GABAB receptor activation of Purkinje cells in cerebellar slices. Neuroscience Research 29, 151160.CrossRefGoogle Scholar
Wagner, P.G. & Dekin, M.S. (1993). GABAB receptors are coupled to a barium-insensitive outward rectifying potassium conductance in premotor respiratory neurons. Journal of Neurophysiology 69, 286289.Google Scholar
Walker, G.A., Ohzawa, I., & Freeman, R.D. (1999). Asymmetric suppression outside the classical receptive field of the visual cortex. Journal of Neuroscience 19, 1053610553.Google Scholar
Walker, G.A., Ohzawa, I., & Freeman, R.D. (2000). Suppression outside the classical cortical receptive field. Visual Neuroscience 17, 369379.CrossRefGoogle Scholar
Yoshimura, Y., Sato, H., Imamura, K., & Watanabe, Y. (2000). Properties of horizontal and vertical inputs to pyramidal cells in the superficial layers of the cat visual cortex. Journal of Neuroscience 20, 19311940.Google Scholar
Yuste, R., Gutnick, M.J., Saar, D., Delaney, K.R., & Tank, D.W. (1994). Ca2+ accumulations in dendrites of neocortical pyramidal neurons: An apical band and evidence for two functional compartments. Neuron 13, 2343.CrossRefGoogle Scholar