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 smyhc1:gfp-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. To investigate how contact-mediated guidance cues are organized along the motor path to exert their function in vivo, we used microscopy-based methods to analyze and quantify motor axon navigation in tnc and col15a1b knock-out fish. We show that motor axon shape and growth rely on the timely expression of the attractive cue Collagen XV-B that locally provides axons with a permissive soft microenvironment and separately organizes the repulsive cue Tenascin C into a unique functional dual topology. Importantly, bioprinted micropatterns that mimic this in vivo ECM topology were sufficient to drive directional motor axon growth. Our study offers evidence that not only the composition of ECM cues but their topology critically influences motor axon navigation in vertebrates with potential applications in regenerative medicine for peripheral nerve injury as regenerating nerves follow their original path.

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. Specifically, methods to visualize and quantify the complex axon arborization are challenging to implement and apply practically. Our study was aimed at developing a robust but simple method of quantification that used ImageJ 2D analysis and compared it with Imaris visualization and analysis of 3D images. We used zebrafish fluorescent transgenic lines to perform in vivo imaging of developing motor neuron axons that adequately reflected the complexity of axonal networks. Our new method, developed on ImageJ, is easy and fast, giving access to new information such as collateral distribution along the axonal shaft. This study describes step-by-step procedures that can be easily applied to a variety of organisms and in vitro systems. Our study provides a basis for further exploration of neural circuits to gain new insights into neuronal disorders and potential therapeutic interventions.

[The role of extracellular matrix in the regeneration of motor nerves]. / Le rôle de la matrice extracellulaire dans la régénération des nerfs moteurs.

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. Regenerating axons are able to return to their synaptic target following their original trajectory. The same guidance cues could be thus involved in motor nerve regeneration. Zebrafish has become a popular model system in understanding the development of the peripheral nervous system. Thanks to the generation of fluorescent transgenic lines and the optical transparency of embryos and larvae, it allows direct visualization of axonogenesis. Additionally, and contrary to humans, its remarkable capacity to regenerate makes it well suited for the study of nerve regeneration. A laser method to ablate nerves in living zebrafish larvae has been developed in our laboratory that, combined with the use of the fluorescent mnx1:gfp zebrafish transgenic line, allows the follow up of the dynamics of the nerve regeneration process. To study the role of ECM proteins present in the axonal path, mutant lines for different ECM proteins (already available in our laboratory or generated in mnx1:gfp fish using CRISPR-Cas9 method) will be used to analyze their role during the regeneration process. These mutant lines for ECM will be crossed with existing fluorescent transgenic lines to visualize different cell types involved in the nerve regeneration, such as macrophages (mfap4:mcherry), neutrophils (mpx:gfp) or even Schwann cells (sox10:mrfp). Overall, this study will depict the role of ECM in nerve regeneration and will provide essential knowledge for the development of new biomaterials to promote the regeneration of injured motor nerves.