Abstract
The balanced action of both pre- and postsynaptic organizers regulates the formation of neuromuscular junctions (NMJ). The precise mechanisms that control the regional specialization of acetylcholine receptor (AChR) aggregation, guide ingrowing axons and contribute to correct synaptic patterning are unknown. Synaptic activity is of central importance and to understand synaptogenesis, it is necessary to distinguish between activity-dependent and activity-independent processes. By engineering a mutated fetal AChR subunit, we used homologous recombination to develop a mouse line that expresses AChR with massively reduced open probability during embryonic development. Through histological and immunochemical methods as well as electrophysiological techniques, we observed that endplate anatomy and distribution are severely aberrant and innervation patterns are completely disrupted. Nonetheless, in the absence of activity AChRs form postsynaptic specializations attracting motor axons and permitting generation of multiple nerve/muscle contacts on individual fibers. This process is not restricted to a specialized central zone of the diaphragm and proceeds throughout embryonic development. Phenotypes can be attributed to separate activity-dependent and -independent pathways. The correct patterning of synaptic connections, prevention of multiple contacts and control of nerve growth require AChR-mediated activity. In contrast, myotube survival and acetylcholine-mediated dispersal of AChRs are maintained even in the absence of AChR-mediated activity. Because mouse models in which acetylcholine is entirely absent do not display similar effects, we conclude that acetylcholine binding to the AChR initiates activity-dependent and activity-independent pathways whereby the AChR modulates formation of the NMJ.
Highlights
The vertebrate neuromuscular junction (NMJ) is a large cholinergic synapse where transmission occurs through acetylcholine (ACh)
A fast channel myasthenic syndrome is caused by a P121 with leucine (P121L) mutation in the AChRe subunit, reducing the postsynaptic response to ACh while retaining a normal ACh receptor (AChR) load on the endplates (Ohno et al, 1996)
The same mutation in recombinant mouse AChR expressed in X. laevis oocytes caused a similar dramatic reduction in ion conductance [15]
Summary
The vertebrate neuromuscular junction (NMJ) is a large cholinergic synapse where transmission occurs through acetylcholine (ACh). It is unclear how the interaction of activitydependent and -independent factors coordinates the differentiation of synaptic elements to achieve the precise development of NMJs. The present study tests the hypothesis that the muscle ACh receptor (AChR) is central to this process. Embryonic AChRs composed of a2bcd subunits (AChRc) cluster on skeletal muscle fibers through prepatterning, a nerve-independent process requiring the muscle-specific tyrosine kinase MuSK [1,2,3] and a growing number of additional proteins. Nerve-derived factors stabilize AChR clusters on the muscle membrane [2,4,5,6]. The mechanisms determining NMJ positioning and the signals stopping axonal branching to form correctly located stable synaptic contacts remain unknown
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