Structure, diversity and synaptic localization of inhibitory glycine receptors

H. Betz; J. Kuhse; M. Fischer; V. Schmieden; B. Laube; A. Kuryatov; D. Langosch; G. Meyer; J. Bormann; N. Rundström; B. Matzenbach; J. Kirsch; M. Ramming

doi:10.1016/0928-4257(94)90087-6

Structure, diversity and synaptic localization of inhibitory glycine receptors

H. Betz, J. Kuhse, M. Fischer, V. Schmieden, B. Laube, A. Kuryatov, D. Langosch, G. Meyer, J. Bormann, N. Rundström, B. Matzenbach, J. Kirsch, M. Ramming

Max-Planck-Inst fur Hirnforschung

Research output: Contribution to journal › Article › peer-review

41 Scopus citations

Abstract

The inhibitory glycine receptor (GlyR) mediates postsynaptic inhibition in spinal cord, brain stem and other regions of the vertebrate central nervous system. Biochemical and molecular approaches have identified different developmentally and regionally regulated GlyR isoforms that result from the differential expression of at least four genes coding for different variants of the ligand-binding α subunit. Molecular studies have allowed identification of GlyR subunit domains implicated in ligand binding, channel formation and receptor assembly. At the postsynaptic membrane, the GlyR colocalizes with a 93-kDa tubulin-binding peripheral membrane protein, gephyrin. Antisense inhibition of gephyrin expression prevents GlyR accumulation at postsynaptic membrane specialization. Thus gephyrin is essential for postsynaptic receptor topology.

Original language	English
Pages (from-to)	243-248
Number of pages	6
Journal	Journal of Physiology Paris
Volume	88
Issue number	4
DOIs	https://doi.org/10.1016/0928-4257(94)90087-6
State	Published - 1994
Externally published	Yes

Keywords

gephyrin
glycine receptor
postsynaptic inhibition
spinal cord
synaptogenesis

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10.1016/0928-4257(94)90087-6

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title = "Structure, diversity and synaptic localization of inhibitory glycine receptors",

abstract = "The inhibitory glycine receptor (GlyR) mediates postsynaptic inhibition in spinal cord, brain stem and other regions of the vertebrate central nervous system. Biochemical and molecular approaches have identified different developmentally and regionally regulated GlyR isoforms that result from the differential expression of at least four genes coding for different variants of the ligand-binding α subunit. Molecular studies have allowed identification of GlyR subunit domains implicated in ligand binding, channel formation and receptor assembly. At the postsynaptic membrane, the GlyR colocalizes with a 93-kDa tubulin-binding peripheral membrane protein, gephyrin. Antisense inhibition of gephyrin expression prevents GlyR accumulation at postsynaptic membrane specialization. Thus gephyrin is essential for postsynaptic receptor topology.",

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author = "H. Betz and J. Kuhse and M. Fischer and V. Schmieden and B. Laube and A. Kuryatov and D. Langosch and G. Meyer and J. Bormann and N. Rundstr{\"o}m and B. Matzenbach and J. Kirsch and M. Ramming",

year = "1994",

doi = "10.1016/0928-4257(94)90087-6",

language = "English",

volume = "88",

pages = "243--248",

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TY - JOUR

T1 - Structure, diversity and synaptic localization of inhibitory glycine receptors

AU - Betz, H.

AU - Kuhse, J.

AU - Fischer, M.

AU - Schmieden, V.

AU - Laube, B.

AU - Kuryatov, A.

AU - Langosch, D.

AU - Meyer, G.

AU - Bormann, J.

AU - Rundström, N.

AU - Matzenbach, B.

AU - Kirsch, J.

AU - Ramming, M.

PY - 1994

Y1 - 1994

N2 - The inhibitory glycine receptor (GlyR) mediates postsynaptic inhibition in spinal cord, brain stem and other regions of the vertebrate central nervous system. Biochemical and molecular approaches have identified different developmentally and regionally regulated GlyR isoforms that result from the differential expression of at least four genes coding for different variants of the ligand-binding α subunit. Molecular studies have allowed identification of GlyR subunit domains implicated in ligand binding, channel formation and receptor assembly. At the postsynaptic membrane, the GlyR colocalizes with a 93-kDa tubulin-binding peripheral membrane protein, gephyrin. Antisense inhibition of gephyrin expression prevents GlyR accumulation at postsynaptic membrane specialization. Thus gephyrin is essential for postsynaptic receptor topology.

AB - The inhibitory glycine receptor (GlyR) mediates postsynaptic inhibition in spinal cord, brain stem and other regions of the vertebrate central nervous system. Biochemical and molecular approaches have identified different developmentally and regionally regulated GlyR isoforms that result from the differential expression of at least four genes coding for different variants of the ligand-binding α subunit. Molecular studies have allowed identification of GlyR subunit domains implicated in ligand binding, channel formation and receptor assembly. At the postsynaptic membrane, the GlyR colocalizes with a 93-kDa tubulin-binding peripheral membrane protein, gephyrin. Antisense inhibition of gephyrin expression prevents GlyR accumulation at postsynaptic membrane specialization. Thus gephyrin is essential for postsynaptic receptor topology.

KW - gephyrin

KW - glycine receptor

KW - postsynaptic inhibition

KW - spinal cord

KW - synaptogenesis

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U2 - 10.1016/0928-4257(94)90087-6

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SN - 0928-4257

VL - 88

SP - 243

EP - 248

JO - Journal of Physiology Paris

JF - Journal of Physiology Paris

IS - 4

ER -

Structure, diversity and synaptic localization of inhibitory glycine receptors

Abstract

Keywords

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