Postsynaptic CaV1.1-driven calcium signaling coordinates presynaptic differentiation at the developing neuromuscular junction

Agrin/Dok-7-induced JPH2 phosphorylation in muscle cells is involved in AChR clustering

The neuromuscular junction (NMJ) performs the crucial function of controlling skeletal muscle contraction. NMJ formation depends on the Agrin/Lrp4/MuSK/Dok-7 signaling pathway. However, signaling downstream of Dok-7 remains incompletely understood. Here we used the phosphorylated iTRAQ technique to identify downstream molecules of Dok-7 in muscle cells. We found 16 Agrin/Dok-7-mediated serine/threonine phosphorylated proteins, and we validated the role of one phosphorylated protein, JPH2, in regulating AChR clustering. Our phosphoproteomics analysis sheds light on the underappreciated signaling network downstream of Agrin/Dok-7, thus providing new clues for understanding pathogenesis and developing treatment methods for neuromuscular diseases.

Spatial transcriptomics in embryonic mouse diaphragm muscle reveals regional gradients and subdomains of developmental gene expression

The murine embryonic diaphragm is a primary model for studying myogenesis and neuro-muscular synaptogenesis, both representing processes regulated by spatially organized genetic programs of myonuclei located in distinct myodomains. However, a spatial gene expression pattern of embryonic mouse diaphragm has not been reported. Here, we provide spatially resolved gene expression data for horizontally sectioned embryonic mouse diaphragms at embryonic days E14.5 and E18.5. These data reveal gene signatures for specific muscle regions with distinct maturity and fiber type composition, as well as for a central neuromuscular junction (NMJ) and a peripheral myotendinous junction (MTJ) compartment. Comparing spatial expression patterns of wild-type mice with those of transgenic mice lacking either the skeletal muscle calcium channel CaV1.1 or β-catenin, reveals curtailed muscle development and dysregulated expression of genes potentially involved in NMJ formation. Altogether, these datasets provide a powerful resource for further studies of muscle development and NMJ formation in the mouse.

Counteractive and cooperative actions of muscle β-catenin and CaV1.1 during early neuromuscular synapse formation

Activity-dependent calcium signals in developing muscle play a crucial role in neuromuscular junction (NMJ) formation. However, its downstream effectors and interactions with other regulators of pre- and postsynaptic differentiation are poorly understood. Here, we demonstrate that the skeletal muscle calcium channel Ca_V1.1 and β-catenin interact in various ways to control NMJ development. They differentially regulate nerve branching and presynaptic innervation patterns during the initial phase of NMJ formation. Conversely, they cooperate in regulating postsynaptic AChR clustering, synapse formation, and the proper organization of muscle fibers in mouse diaphragm. Ca_V1.1 does not directly regulate β-catenin expression but differentially controls the activity of its transcriptional co-regulators TCF/Lef and YAP. These findings suggest a crosstalk between Ca_V1.1 and β-catenin in the activity-dependent transcriptional regulation of genes involved in specific pre- and postsynaptic aspects of NMJ formation.

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Neuromuscular junction formation requires either muscle calcium or β-catenin signaling

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Complementary actions of Ca_V1.1 and β-catenin control presynaptic innervation patterns

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Parallel actions of Ca_V1.1 and β-catenin are crucial for postsynaptic AChR clustering

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Loss of Ca_V1.1 differentially regulates activity of β-catenin targets TCF/Lef and YAP

LKB1 coordinates neurite remodeling to drive synapse layer emergence in the outer retina

Structural changes in pre and postsynaptic neurons that accompany synapse formation often temporally and spatially overlap. Thus, it has been difficult to resolve which processes drive patterned connectivity. To overcome this, we use the laminated outer murine retina. We identify the serine/threonine kinase LKB1 as a key driver of synapse layer emergence. The absence of LKB1 in the retina caused a marked mislocalization and delay in synapse layer formation. In parallel, LKB1 modulated postsynaptic horizontal cell refinement and presynaptic photoreceptor axon growth. Mislocalized horizontal cell processes contacted aberrant cone axons in LKB1 mutants. These defects coincided with altered synapse protein organization, and horizontal cell neurites were misdirected to ectopic synapse protein regions. Together, these data suggest that LKB1 instructs the timing and location of connectivity in the outer retina via coordinate regulation of pre and postsynaptic neuron structure and the localization of synapse-associated proteins.