AI Article Synopsis
- - The study is about how certain proteins called Slits help guide nerve cells, specifically the growth cones, so they don’t go back after crossing the middle part of the spine.
- - Researchers looked at how these Slits are found in clusters and how they connect with special cells called glial cells to help direct the growth cones in the right way.
- - They also created a special mouse to see how a different protein shared with Slits works, which showed that SlitC helps keep growth cones moving in a straight path through the spine.
Article Abstract
Spinal commissural axon navigation across the midline in the floor plate requires repulsive forces from local Slit repellents. The long-held view is that Slits push growth cones forward and prevent them from turning back once they became sensitized to these cues after midline crossing. We analyzed with fluorescent reporters Slits distribution and FP glia morphology. We observed clusters of Slit-N and Slit-C fragments decorating a complex architecture of glial basal process ramifications. We found that PC2 proprotein convertase activity contributes to this pattern of ligands. Next, we studied Slit-C acting via PlexinA1 receptor shared with another FP repellent, the Semaphorin3B, through generation of a mouse model baring PlexinA1 mutation abrogating SlitC but not Sema3B responsiveness, manipulations in the chicken embryo, and ex vivo live imaging. This revealed a guidance mechanism by which SlitC constantly limits growth cone exploration, imposing ordered and forward-directed progression through aligned corridors formed by FP basal ramifications.
Download full-text PDF |
Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7775108 | PMC |
| http://dx.doi.org/10.7554/eLife.63205 | DOI Listing |
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