Loss of ACTA1 leads to delayed γ-AChR / ε-AChR switch in skeletal muscle in mice

Skeletal muscle actin forms the core structural component of thin filaments, which interact with thick filaments to generate contractile force. In addition to force production, the character of muscle contraction activity itself is thought to provide mechanical cues that influence synaptic development and maturation. In mouse skeletal muscle there is an early post-natal switch from embryonic forms of actin to the adult isoform, ACTA1, which increases both filament stability and force production. Newborn mice deficient for ACTA1 ( Acta1 ^−/− ), although initially able to breath, move and suckle, develop profound muscle weakness and die during the early neonatal period, despite a compensatory, increase in expression of embryonic actins. We took advantage of this to better understand the response of the neuromuscular junction (NMJ) to a disruption in contractility and activity-dependent signaling during development. Morphological analyses of the diaphragm in Acta1 ^−/− mice revealed that the patterning and formation of the NMJ proceed normally through postnatal day 5 (P5), the day at which pups begin to die. Short-term synaptic plasticity, assessed as the endplate potential (EPP) response to paired-pulse stimulation, was also unchanged, indicating normal presynaptic release of neurotransmitters. In contrast, electrophysiological recordings demonstrated significantly prolonged rise and decay kinetics of miniature and evoked endplate potentials, indicating altered postsynaptic receptor properties. Consistent with these functional changes, quantitative real-time PCR showed a reduced ratio of ε- to γ-acetylcholine receptor (AChR) subunit mRNA, reflecting a delay in the developmental switch from embryonic γ-containing to adult ε-containing AChRs. Together, these findings indicate that α-skeletal actin is dispensable for early NMJ morphogenesis but is required for timely postsynaptic receptor maturation, demonstrating a critical role for muscle contractile activity in coordinating synaptic development at the NMJ.