Co-culture of postnatal mouse spinal cord and skeletal muscle explants as an experimental model of neuromuscular interactions.

The intercommunication between nerves and muscles plays an important role in the functioning of our body, and its failure leads to severe neuromuscular disorders such as spinal muscular atrophy and amyotrophic lateral sclerosis. Understanding the cellular and molecular mechanisms underlying nerve-muscle interactions and mediating their mutual influence is an integral part of strategies aimed at curing neuromuscular diseases. Here, we propose a novel ex vivo experimental model for the spinal cord (SC) and skeletal muscle interactions which for the first time utilizes only fully formed (but not yet quite functional) postnatal tissues. The model represents an organotypic co-culture comprising a longitudinal slice of the mouse postnatal SC and an extensor digitorum longus (EDL) muscle explant placed in the "damage zone" of transversally dissected longitudinal slice of the SC. Using this model, we have shown that SC tissue stimulates muscle contractions and reduces the area occupied by acetylcholine receptors on muscle surface. In turn, EDL muscles stimulate the growth of SC-derived neurites. Thus, our organotypic model allows one to assess the mutual influence of neurons and muscles in a nearly natural setting which maintains the architecture and cellular composition of intact tissues. Therefore, this model may provide an effective platform for studying molecular and cellular mechanisms linked to defective neuromuscular interactions in associated pathologies.