Paralytic Zebrafish Lacking Acetylcholine Receptors Fail to Localize Rapsyn Clusters to the Synapse

Overview

Journal J Neurosci

Specialty Neurology

Date 2001 Jul 24

PMID 11466415

Citations 65

Authors

F Ono

S Higashijima

A Shcherbatko

J R Fetcho

P Brehm

Affiliations

Soon will be listed here.

Abstract

Physiological analysis of two lines of paralytic mutant zebrafish, relaxed and sofa potato, reveals defects in distinct types of receptors in skeletal muscle. In sofa potato the paralysis results from failed synaptic transmission because of the absence of acetylcholine receptors, whereas relaxed mutants lack dihydropyridine receptor-mediated release of internal calcium in response to the muscle action potential. Synaptic structure and function appear normal in relaxed, showing that muscle paralysis per se does not impede proper synapse development. However, sofa potato mutants show incomplete development of the postsynaptic complex. Specifically, in the absence of ACh receptors, clusters of the receptor-aggregating protein rapsyn form in the extrasynaptic membrane but generally fail to localize to the subsynaptic region. Our results indicate that, although rapsyn molecules are capable of self-aggregation, interaction with ACh receptors is required for proper subsynaptic localization.

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