Netrin-1 is an evolutionarily conserved secreted extracellular matrix protein discovered using genetic and biochemical screens for its role in axon guidance at the central nervous system (CNS) midline1,2. Netrin-1 is expressed by cells localized at CNS midline, such as the floor plate in vertebrate embryos1,3. Growth cone turning assays and 3D gel diffusion assays showed that netrin-1 can attract commissural axons2,4–6. Loss-of-function experiments further demonstrated that commissural axon extension to the midline is severely impaired in absence of netrin-13,7–9. Together these data support a model in which commissural axons are attracted by a netrin-1 gradient diffusing from the midline. Here, we selectively ablated netrin-1 expression in floor plate cells using a Netrin-1 conditional mouse line. We found that hindbrain and spinal cord commissural axons develop normally in absence of floor plate-derived netrin-1. Furthermore, we show that netrin-1 is highly expressed by cells in the ventricular zone with the potential to release it at the pial surface where it binds to commissural axons. Importantly, netrin-1 deletion from the ventricular zone phenocopies commissural axon guidance defects previously described in Netrin-1 knockout mice. These results show that the classical textbook view that attraction of commissural axons is mediated by a gradient of floor plate-derived netrin-1 is inaccurate and that netrin-1 primarily acts locally by promoting growth cone adhesion.
Highlights d Both floor-plate-and VZ-derived netrin-1 guide spinal cord commissural axons d Commissural axons go astray to the midline in the absence of floor plate netrin-1 d Commissural axon fasciculation is modified in the absence of VZ netrin-1 d Midline crossing mechanisms differ between the spinal cord and hindbrain
During the development of the central nervous system (CNS), only motor axons project into peripheral nerves. Little is known about the cellular and molecular mechanisms that control the development of a boundary at the CNS surface and prevent CNS neuron emigration from the neural tube. It has previously been shown that a subset of spinal cord commissural axons abnormally invades sensory nerves in hypomorphic embryos and knockouts. However, whether netrin 1 also plays a similar role in the brain is unknown. In the hindbrain, precerebellar neurons migrate tangentially under the pial surface, and their ventral migration is guided by netrin 1. Here, we show that pontine neurons and inferior olivary neurons, two types of precerebellar neurons, are not confined to the CNS in and mutant mice, but that they invade the trigeminal, auditory and vagus nerves. Using a conditional knockout, we show that netrin 1, which is released at the pial surface by ventricular zone progenitors is responsible for the CNS confinement of precerebellar neurons. We propose, that netrin 1 distribution sculpts the CNS boundary by keeping CNS neurons in netrin 1-rich domains.
Highlights d Depletion of floor plate Netrin-1 impairs midline crossing of corticospinal axons d Shh::cre;Ntn1 lox/lox mice have functional ipsilateral corticospinal projections d Lateralization of voluntary motor controls is selectively altered in these mice d These mice represent a model for human congenital mirror movements
In human, execution of unimanual movements requires lateralized activation of the primary motor cortex, which then transmits the motor command to the contralateral hand through the crossed corticospinal tract (CST). Mutations in NETRIN-1 alter motor control lateralization, leading to congenital mirror movements. To address the role of midline Netrin-1 on CST development and subsequent motor control, we analyzed the morphological and functional consequences of floor-plate Netrin-1 depletion in conditional knock-out mice (Shh::cre;Ntn1 lox/lox mice). Here, we show that depletion of floor plate Netrin-1 critically disrupts midline crossing of the CST, whereas the other commissural systems are mostly preserved. The CST defect results in abnormal but functional ipsilateral projections, and is associated with abnormal symmetric movements. Therefore, our study reveals a new role for Netrin-1 in CST development. It also describes a unique mouse model recapitulating characteristics of human congenital mirror movements, through abnormal CST decussation.
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