Dual topologies of myotomal collagen XV and Tenascin C act in concert to guide and shape developing motor axons.

During development, motor axons are guided toward muscle target by various extrinsic cues including extracellular matrix (ECM) proteins whose identities and cellular source remain poorly characterized. Here, using single-cell RNAseq of sorted GFP cells from -injected zebrafish embryos, we unravel the slow muscle progenitors (SMP) pseudotemporal trajectory at the single-cell level and show that differentiating SMPs are a major source of ECM proteins. The SMP core-matrisome was characterized and computationally predicted to form a basement membrane-like structure tailored for motor axon guidance, including basement membrane-associated ECM proteins, as collagen XV-B, one of the earliest core-matrisome gene transcribed in differentiating SMPs and the glycoprotein Tenascin C.

Quantitative Image Analysis of Axonal Morphology in In Vivo Model.

Quantifying axonal branching is crucial for understanding neural circuit function, developmental and regeneration processes and disease mechanisms. Factors that regulate patterns of axonal arborization and tune neuronal circuits are investigated for their implication in various disorders in brain connectivity. The lack of a reliable and user-friendly method makes the quantitative analysis of axon morphology difficult.

[The role of extracellular matrix in the regeneration of motor nerves].

The motor neurons (MN) form the ultimate route to convey the commands from the central nervous system to muscles. During development, MN extend axons that follow stereotyped trajectories to their muscle targets, guided by various attractive and repulsive molecular cues. Extracellular matrix (ECM) is a major source of guidance cues, but its role in axonal development and regeneration remains poorly documented.