“We found nerve cells do this in two ways, either acting as barriers preventing cell bodies to move further than they need to, or by acting as guides opening a corridor that the cell bodies can travel along”, she says.
The nervous system is analogous to a biological “computer” with different nerve cells forming connections that continuously send neural information around the spinal cord, brain and body and back again. Each nerve cell has a kind of “GPS coordinate” and exactly where nerve cells are physically located is very important so they can connect correctly with other nerve cells.
When nerve cells are in the wrong place neural information is not transmitted properly and it results in dysfunction and neurodevelopmental disorders such as lissencephaly, Kallmann syndrome and periventricular heterotopia. These misplacements can also happen in very common developmental disorders such as dyslexia and autistic spectrum disorders but it is not fully clear what role such misplacements play in these cases.
“Because nerve cell position is so important in normal nervous system function and dysfunction we wanted to find out how nerve cells position themselves in the first place. This study uncovered an exciting new mechanism for how this happens” Sara Wilson says.
Two of the main parts of a nerve cell are the central part (called the cell body) and a very long part like a “wire” (called the axon) that connects with and sends information to other nerve cells. It is important for both of these parts to be in the right place to get the nervous system to work properly.
The axons usually group together and form structures similar to corridors heading in a certain direction. Using genetic changes in mouse embryos to disrupt these axonal corridors (make them head in a different direction), her research group at Umeå Centre of Molecular Medicine, now at the Department of Molecular Biology, Umeå University, found that cell bodies from nerve cells also end up in the wrong place.
“This means the axons from some nerve cells are influencing the position of the cell bodies of other nerve cells meaning that the nerve cells are creating a “map” for other nerve cells to find their way” Sara Wilson says.
“This is the first time that axons have been shown to act as barriers and it could have important implications for understanding how the nervous system forms in all animals, including humans” Sara Wilson concludes.
Overall, this work and other work from the group focuses on understanding the mechanisms (genetic, cellular and molecular) of how the precise “anatomy” of the nervous system first forms and how that influences neuronal function and dysfunction. This basic science research has important medical implications for understanding the cause of some neurodevelopmental disorders: For example do the genes that are associated with such disorders generally control cell body guidance and is that what leads to dysfunction?
“It can also give clues as to how to grow axons during regeneration following damage or disease of the nervous system. Can we “force” regenerating neurons to connect properly? In the future, we plan to continue this basic research and find medical research teams to collaborate with to see if our findings are beneficial in these medical contexts” Sara Wilson says.
About the study:
Laumonnerie, C. Tong, Y.G., Alstermark, H. and Wilson S.I. Commissural axonal corridors instruct neuronal migration in the mouse spinal cord. Nature Communications. 2015, 6:7028, doi: 10.1038/ncomms8028.
For more information, please contact:
Sara Wilson, Department of Molecular Biology, Umeå University
Phone: +46 90 7852523, +46 76 8481068
Images: Axons in red and neuronal cell bodies in green shows cell bodies following the red axons in the normal embryo (left) and when the axons are misplaced in the right image the cell bodies move to the wrong place too.
Photo: Christophe Laumonnerie